Regulation of intestinal growth in response to variations in energy supply and demand.

The growth of the intestine requires energy, which is known to be met by catabolism of ingested nutrients. Paradoxically, during whole body energy deficit including calorie restriction, the intestine grows in size. To understand how and why this happens, we reviewed data from several animal models of energetic challenge. These were bariatric surgery, cold exposure, lactation, dietary whey protein intake and calorie restriction. Notably, these challenges all reduced the adipose tissue mass, altered hypothalamic neuropeptide expression and increased intestinal size. Based on these data, we propose that the loss of energy in the adipose tissue promotes the growth of the intestine via a signalling mechanism involving the hypothalamus. We discuss possible candidates in this pathway including data showing a correlative change in intestinal (ileal) expression of the cyclin D1 gene with adipose tissue mass, adipose derived-hormone leptin and hypothalamic expression of leptin receptor and the pro-opiomelanocortin gene. The ability of the intestine to grow in size during depletion of energy stores provides a mechanism to maximize assimilation of ingested energy and in turn sustain critical functions of tissues important for survival.

Nutrient regulation of enteroendocrine cellular activity linked to cholecystokinin gene expression and secretion.

The hormone cholecystokinin is produced by the enteroendocrine I cells in the intestine, and it plays an important role in a number of physiological processes including digestion and food intake. Recent data suggest that cholecystokinin gene expression and protein secretion are regulated by macronutrients. The mechanism involves a change in intracellular levels of cAMP and Ca(+2), brought about by the activity of a number of nutrient-responsive G protein-coupled receptors, nutrient transporters, ion channels and intracellular enzymes. How these intracellular responses could lead to gene expression and protein secretion are discussed along with new directions for future investigation.

Photoperiod regulates genes encoding melanocortin 3 and serotonin receptors and secretogranins in the dorsomedial posterior arcuate of the Siberian hamster.

The mechanism(s) involved in the regulation of the seasonal-appropriate body weight of the Siberian hamster are currently unknown. We have identified photoperiodically regulated genes including VGF in a sub-region of the arcuate nucleus termed the dorsomedial posterior arcuate (dmpARC). Gene expression changes in this nucleus so far account for a significant number of those reported as photoperiodically regulated and are therefore likely to contribute to seasonal physiological responses of the hamsters. The present study aimed to identify additional genes expressed in the dmpARC regulated by photoperiod that could be involved in regulating the activity of this nucleus with respect to seasonal physiology of the Siberian hamster. Using laser capture microdissection coupled with a microarray analysis and a candidate gene approach, we have identified several photoperiodically regulated genes in the dmpARC that are known to have roles in secretory and intracellular signalling pathways. These include secretogranin (sg) III and SgVI (secretory pathway), melanocortin 3 receptor (MC3-R) and serotonin (5-HT) receptors 2A and 7 (signalling pathway), all of which increase in expression under a short photoperiod. The spatial relationship between receptor signalling and potential secretory pathways was investigated by dual in situ hybridisation, which revealed that 5-HT2A and 5-HT7 receptors are expressed in neurones expressing VGF mRNA and that a sub-population (approximately 40%) of these neurones express MC3-R. These gene expression changes in dmpARC neurones may reflect the functional requirement of these neurones for seasonal physiological responses of the hamster.

G protein-coupled receptor 101 mRNA expression in the mouse brain: altered expression in the posterior hypothalamus and amygdala by energetic challenges.

GPCR101 is a recently identified orphan G protein-coupled receptor (GPCR) expressed abundantly in the human and mouse hypothalamus. In the absence of a ligand, a direct approach to determine the function(s) of this receptor is not possible. However, clues to the possible functions of GPCR101 may yield from information on the distribution of the receptor and the effect of in vivo manipulation upon the expression level of the receptor. In situ hybridisation on mouse brain sections revealed GPCR101 expression in a number of nuclei, including the amygdala, lateral parabrachial nucleus and nucleus of the solitary tract, as well as in the arcuate nucleus, posterior hypothalamus and paraventricular nucleus of the hypothalamus. Food-deprivation was found to increase GPCR101 mRNA level in the posterior hypothalamus and amygdala. In obese mice bearing the ob gene mutation, GPCR101 mRNA level decreased in the posterior hypothalamus and remained unaltered in the amygdala. By contrast, in both nuclei, GPCR101 mRNA level did not change significantly in obese ob/ob mice after intraperitoneal injection of leptin or in mice fed with a high fat diet. These data suggest that GPCR101 mRNA expression in the posterior hypothalamus and amygdala is regulated by a factor(s) other than leptin. Dual in situ hybridisation was used to establish the relationship between GPCR101 and neuropeptides expressed in the hypothalamus. In the arcuate nucleus, GPCR101 mRNA was expressed in approximately half of the population of neurones expressing the mRNA for the anorexigenic neuropeptide, pro-opiomelanocortin, which suggests a potential functional relationship.

Precursor-protein convertase 1 gene expression in the mouse hypothalamus: differential regulation by ob gene mutation, energy deficit and administration of leptin, and coexpression with prepro-orexin.

The expression of precursor-protein convertase (PC)1, PC2 and paired basic amino acid cleaving enzyme four mRNA was studied by in situ hybridisation in regions of the hypothalamus involved in energy regulation in relation to obese (ob) gene mutation and energy deficit. PC1 gene was differentially expressed in hypothalamic nuclei of mice from different genetic backgrounds or energetic status, whereas no differences in expression were observed for either the PC2 or paired basic amino acid cleaving enzyme four genes. In obese ob/ob mice, PC1 mRNA levels were increased in the paraventricular nucleus, decreased in the lateral hypothalamus and unchanged in the ventromedial nucleus and arcuate nucleus relative to lean controls. In response to intraperitoneal injection of murine leptin, PC1 mRNA levels in obese ob/ob mice decreased in the arcuate nucleus, increased in the lateral hypothalamus and were unchanged in both the paraventricular nucleus and ventromedial nucleus. In mice deprived of food for 24 h, PC1 mRNA levels were reduced in the ventromedial nucleus, increased in the lateral hypothalamus and unchanged in the paraventricular nucleus and arcuate nucleus relative to ad libitum-fed controls. Overall, whilst the data show effects related to leptin and energetic status, they do not support a strong and consistent link between PC1 gene expression and energy balance. This suggests that if PC1 is important to the control of energy balance then protein expression and activity, rather than gene expression may be the more critical parameters of regulation. The relationship between PC1 and candidate energy balance-related genes in the lateral hypothalamus was investigated by dual in situ hybridisation. PC1 mRNA was localised in prepro-orexin mRNA expressing neurons in the lateral hypothalamus, which suggests a functional relationship.