Rats with a truncated ghrelin receptor (GHSR) do not respond to ghrelin, and show reduced intake of palatable, high-calorie food.

Ghrelin, a peptide hormone produced by the stomach, is the endogenous ligand for the Growth Hormone Secretagogue Receptor (GHSR). Ghrelin acts on the GHSR to increase food intake, appetitive behaviors, and adiposity. Recently, a rat model with a null mutation to the GHSR gene (FHH-GHSR(m1/Mcwi)) was generated and used in behavioral studies, but the basic metabolic phenotype of this strain as well as that of the background strain (Fawn Hooded Hypertensive, FHH) has not been characterized in detail. Here we compared male FHH-GHSR(m1/Mcwi) rats with their wild-type littermates (FHH-WT) in a number of metabolic parameters. In the 24h of recovery following an acute overnight fast, FHH-GHSR(m1/Mcwi) rats consumed less food than FHH-WT animals, and relative to their body weights, adult FHH-GHSR(m1/Mcwi) rats consumed fewer calories when placed on a high-fat diet. Despite this, FHH-GHSR(m1/Mcwi) rats did not show a difference in diet-induced obesity or weight gain. Fasted FHH-GHSR(m1/Mcwi) rats exhibited increased Agouti-Related Peptide (AgRP) and Neuropeptide Y (NPY) expression in the Arcuate Nucleus (ARC), indicative of altered central regulation of feeding and energy balance. FHH-GHSR(m1/Mcwi) rats exhibited lower levels of home cage locomotor behavior over the entire light/dark cycle, and reduced levels of food anticipatory activity when placed on a restricted feeding schedule. Finally, FHH-GHSR(m1/Mcwi) rats consumed less of a palatable dessert (cookie dough) given after the completion of the scheduled meal. Altogether, our data show that rats lacking a functional GHSR tend to eat less than their wild-type counterparts in the face of acute fasts, chronic high-fat diet exposure, and exposure to a palatable dessert, despite not showing differences in body weight and glucose homeostasis that are characteristic of GHSR null mice. These data indicate that many, but not all responses to GHSR ablation are conserved between rats and mice. The FHH-GHSR(m1/Mcwi) rat thus represents a novel and useful model for studying GHSR function in rats.

Novel Regulator of Acylated Ghrelin, CF801, Reduces Weight Gain, Rebound Feeding after a Fast, and Adiposity in Mice.

Ghrelin is a 28 amino acid hormonal peptide that is intimately related to the regulation of food intake and body weight. Once secreted, ghrelin binds to the growth hormone secretagogue receptor-1a, the only known receptor for ghrelin and is capable of activating a number of signaling cascades, ultimately resulting in an increase in food intake and adiposity. Because ghrelin has been linked to overeating and the development of obesity, a number of pharmacological interventions have been generated in order to interfere with either the activation of ghrelin or interrupting ghrelin signaling as a means to reducing appetite and decrease weight gain. Here, we present a novel peptide, CF801, capable of reducing circulating acylated ghrelin levels and subsequent body weight gain and adiposity. To this end, we show that IP administration of CF801 is sufficient to reduce circulating plasma acylated ghrelin levels. Acutely, intraperitoneal injections of CF801 resulted in decreased rebound feeding after an overnight fast. When delivered chronically, they decreased weight gain and adiposity without affecting caloric intake. CF801, however, did cause a change in diet preference, decreasing preference for a high-fat diet and increasing preference for regular chow diet. Given the complexity of ghrelin receptor function, we propose that CF801, along with other compounds that regulate ghrelin secretion, may prove to be a beneficial tool in the study of the ghrelin system, and potential targets for ghrelin-based obesity treatments without altering the function of ghrelin receptors.

Many mouths to feed: the control of food intake during lactation.

Providing nutrients to their developing young is perhaps the most energetically demanding task facing female mammals. In this paper we focus primarily on studies carried out in rats to describe the changes in the maternal brain that enable the dam to meet the energetic demands of her offspring. In rats, providing milk for their litter is associated with a dramatic increase in caloric intake, a reduction in energy expenditure and changes in the pattern of energy utilization as well as storage. These behavioral and physiological adaptations result, in part, from alterations in the central pathways controlling energy balance. Differences in circulating levels of metabolic hormones such as leptin, ghrelin and insulin as well as in responsiveness to these signals between lactating and nonlactating animals, contribute to the modifications in energy balance pathways seen postpartum. Suckling stimulation from the pups both directly, and through the hormonal state that it induces in the mother, plays a key role in facilitating these adaptations.