Kanishka N. Nilaweera

Neuromedin U and Neuromedin U receptor-2 expression in the mouse and rat hypothalamus: effects of nutritional status

Neuromedin U (NMU) has been associated with the regulation of food‐intake and energy balance in rats. The objective of this study was to identify the sites of gene expression for NMU and the NMU receptor‐2 (NMU2R) in the mouse and rat hypothalamus and ascertain the effects of nutritional status on the expression of these genes. In situ hybridization studies revealed that NMU is expressed in several regions of the mouse hypothalamus associated with the regulation of energy balance. Analysis of NMU expression in the obese ob/ob mouse revealed that NMU mRNA levels were elevated in the dorsomedial hypothalamic (DMH) nucleus of obese ob/ob mice compared to lean litter‐mates. In addition, NMU mRNA levels were elevated in the DMH of mice fasted for 24 h relative to ad libitum fed controls. The pattern of expression of NMU and NMU2R were more widespread in the hypothalamus of mice than rats. These data provide the first detailed anatomical analysis of the NMU and NMU2R expression in the mouse and advance our knowledge of expression in the rat. The data from the obese rodent models supports the hypothesis that NMU is involved in the regulation of nutritional status.

Effects of Manipulating Hypothalamic Triiodothyronine Concentrations on Seasonal Body Weight and Torpor Cycles in Siberian Hamsters

Siberian hamsters display photoperiodically regulated annual cycles in body weight, appetite, and reproduction. Previous studies have revealed a profound up-regulation of type 3 deiodinase (DIO3) mRNA in the ventral ependyma of the hypothalamus associated with hypophagia and weight loss in short-day photoperiods. DIO3 reduces the local availability of T(3), so the aim of this study was to test the hypothesis that decreased hypothalamic T(3) availability underlies the short-day-induced catabolic state. The experimental approach was to determine whether a local increase in T(3) in the hypothalamus of hamsters exposed to short days could reverse the behavioral and physiological changes induced by this photoperiod. In study 1, microimplants releasing T(3) were placed bilaterally into the hypothalamus. This treatment rapidly induced a long-day phenotype including increased appetite and body weight within 3 wk of treatment and increased fat mass and testis size by the end of the 10-wk study period. In study 2, hypothalamic T(3) implants were placed into hamsters carrying abdominal radiotelemetry implants. Again body weight increased significantly, and the occurrence of winter torpor bouts was dramatically decreased to less than one bout per week, whereas sham-implanted hamsters entered torpor up to six times a week. Our findings demonstrate that increased central T(3) induces a long-day metabolic phenotype, but in neither study was the molt cycle affected, so we infer that we had not disrupted the initial detection of photoperiod. We conclude that hypothalamic thyroid hormone availability plays a key role in seasonal regulation of appetite, body weight, and torpor.

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.

Hypothalamic bHLH transcription factors are novel candidates in the regulation of energy balance.

The basic helix–loop–helix transcription factors, neurological basic‐helix–loop–helix‐2 (Nhlh‐2), neurogenic differentiation‐1 (NeuroD‐1) and single minded‐1 (Sim‐1) could have roles in energy balance regulation, although supporting evidence is inconclusive. This study in mice provides further evidence that Nhlh‐2 and NeuroD‐1 are involved in energy balance regulation. In situ hybridization was used to study the expression of the genes in relation to physiological status and genetic background within hypothalamic nuclei that are involved in energy balance regulation. These studies show reduced expression of Nhlh‐2 mRNA in the arcuate (ARC) nucleus and NeuroD‐1 mRNA in the paraventricular (PVN) nucleus in obese ob/ob and 24 h food‐deprived mice relative to respective controls, suggesting regulation by leptin. Interestingly, Nhlh‐2 mRNA expression is reduced in obese db/db mice, whereas NeuroD‐1 remains unchanged, suggesting different mechanisms of regulation by leptin of these two genes. To study the role of leptin in the regulation of these genes, leptin was injected intraperitoneally in obese ob/ob mice and mRNA expression evaluated after 1 h or 4 h, or after twice‐daily injection for 7 days. None of these regimes restored Nhlh‐2 or NeuroD‐1 to wild‐type mRNA levels. These latter data suggest either that the regulation of the Nhlh‐2 and NeuroD‐1 genes by leptin is indirect or that the apparent leptin insensitivity of the gene expression reflects a developmental deficit that is a consequence of the phenotype of the obese ob/ob mice. The relationship between Nhlh‐2 and candidate energy balance‐related genes was studied by dual in situ hybridization. Nhlh‐2 mRNA was coexpressed in a subpopulation (30%) of ARC neurons expressing pro‐opiomelanocortin (POMC) mRNA, suggesting a potential functional relationship.

Hypothalamic thyroid hormone in energy balance regulation.

Thyroid hormone has been known for decades as a hormone with profound effects on energy expenditure and ability to control weight. The regulation of energy expenditure by thyroid hormone primarily occurs via regulation of the activity, or expression, of uncoupling proteins in peripheral tissues. However, mechanistically this requires a signal from the brain to change circulating levels of thyroxine and thyroid hormone or increased sympathetic drive to peripheral tissues to alter local thyroid hormone levels via increased expression of type 2 deiodinase. However, little consideration has been given to the potential role and involvement of thyroid hormones action in the brain in the regulation of energy balance. Recent evidence implicates thyroid hormone as a shortterm signal of energy deficit imposed by starvation. Furthermore, thyroid hormone action within the hypothalamus is involved in adjusting long-term energy expenditure in seasonal animals which endure food shortages in winter. Evidence from several studies suggests that regulation of type 2 and type 3 deiodinase enzymes in tanycytes of the third ventricle are gatekeepers of thyroid hormone levels in the hypothalamus. This paper reviews some of the evidence for the role of deiodinase enzymes and the actions of thyroid hormone in the hypothalamus in the regulation of energy balance.

Photoperiodic regulation of glycogen metabolism, glycolysis, and glutamine synthesis in tanycytes of the Siberian hamster suggests novel roles of tanycytes in hypothalamic function.

The objective of this study is to investigate the impact of photoperiod on the temporal and spatial expression of genes involved in glucose metabolism in the brain of the seasonal mammal Phodopus sungorus (Siberian hamster). In situ hybridization was performed on brain sections obtained from male hamsters held in long photoperiod (high body weight and developed testes) or short photoperiod (reduced body weight with testicular regression). This analysis revealed upregulation in expression of genes involved in glycogen and glucose metabolism in short photoperiod and localized to the tanycyte layer of the third ventricle. On the basis of these data and a previously identified photoperiod‐dependent increase in activity of neighboring hypothalamic neurons, we hypothesized that the observed expression changes may reflect alteration in either metabolic fuel or precursor neurotransmitter supply to surrounding neurons. Gene expression analysis was performed for genes involved in lactate and glutamate transport. This analysis showed that the gene for the lactate transporter MCT2 and glutamate transporter GLAST was decreased in the tanycyte layer in short photoperiod. Expression of mRNA for glutamine synthetase, the final enzyme in the synthesis of the neuronal neurotransmitter precursor, glutamine, was also decreased in short photoperiod. These data suggest a role for tanycytes in modulating glutamate concentrations and neurotransmitter supply in the hypothalamic environment.

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.

G protein-coupled receptor 101 mRNA expression in supraoptic and paraventricular nuclei in rat hypothalamus is altered by pregnancy and lactation.

In a previous study performed in mouse models of energetic challenge, there was evidence to suggest that the orphan G protein-coupled receptor GPCR101 may have a role in the regulation of energy balance. To further investigate this possibility, we utilised in situ hybridisation to determine the effect of energetic challenges experienced by pregnant and lactating rats on GPCR101 mRNA expression. In the rat hypothalamus, GPCR101 mRNA expression was detected in a number of hypothalamic nuclei. During pregnancy and lactation, GPCR101 mRNA level remained unchanged in most nuclei, but had increased in the supraoptic nucleus by the end of pregnancy and remained elevated during lactation. GPCR101 mRNA expression showed a similar pattern of expression in the rostral ventromedial parvocellular subdivision of the paraventricular nucleus. A common feature of these two nuclei is the production of the peptide oxytocin. Dual in situ hybridisation revealed GPCR101 and oxytocin mRNA co-expression in neurons of these two nuclei. In the supraoptic nucleus, in situ hybridisation revealed that the temporal regulation of oxytocin and GPCR101 mRNA expression were similar. In the paraventricular nucleus, although temporal changes in oxytocin mRNA expression were similar to GPCR101, the spatial expression of the two mRNA species was different; in contrast to GPCR101, oxytocin mRNA expression changed in both parvo- and magnocellular neurons during lactation. In conclusion, increased GPCR101 mRNA expression in supraoptic and paraventricular nuclei from late pregnancy to late lactation may reflect the functional importance of this receptor in the regulation of neurons of these nuclei during this period.