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.
Mesodermal tissue with heart forming potential (cardiogenic mesoderm) is induced during gastrulation. This cardiogenic mesoderm later differentiates into heart muscle tissue (myocardium) and non-muscular heart tissue. Inhibition of Wnt/β-catenin signaling is known to be required early for induction of cardiogenic mesoderm; however, the identity of the inhibiting Wnt signal itself is still elusive. We have identified Wnt6 in Xenopus as an endogenous Wnt signal, which is expressed in tissues close to and later inside the developing heart. Our loss-of-function experiments show that Wnt6 function is required in the embryo to prevent development of an abnormally large heart muscle. We find, however, that Wnt6 is not required as expected during gastrulation stages, but later during organogenesis stages just before cells of the cardiogenic mesoderm begin to differentiate into heart muscle (myocardium). Our gain-of-function experiments show that Wnt6 and also activated canonical Wnt/β-catenin signaling are capable of restricting heart muscle development at these relatively late stages of development. This repressive role of Wnt signaling is mediated initially via repression of cardiogenic transcription factors, since reinstatement of GATA function can rescue expression of other cardiogenic transcription factors and downstream cardiomyogenic differentiation genes.
We have shown that superoxide anion (O2-) production by the osteoclast can be used as an index of the osteoclast activity since the agents that inhibit and stimulate the osteoclast also diminish and stimulate O2- production respectively. Therefore, we have investigated the mechanism of parathyroid hormone (PTH)-mediated stimulation of osteoclast function in terms of its effect on O2- generation. The determination of O2- generation was carried out by employing cytochrome c immobilised on a surface-modified gold electrode. The basal level of free radical production by the osteoblast-like cells (ROS 17/2.8) was 10(4)-fold lower than by osteoclasts cultured on bone. PTH had no acute effect on free radical production by the osteoblasts. The exposure of the osteoclasts cultured on bone to PTH led to a dramatic and immediate stimulation of O2- generation which was unaffected by the presence of ROS 17/2.8 cells. The osteoclasts co-cultured with ROS 17/2.8 cells and exposed to PTH for 3 h were also found to produce greater stimulation of O2- than the osteoclasts exposed to PTH alone. A competitive leukotriene D4 antagonist REV 5901, which also inhibits 5-lipoxygenase, did not block O2- generation by osteoclasts cultured alone or in the presence of osteoblasts. Therefore, we conclude that PTH directly stimulates osteoclasts to produce O2-; this may be the main mode of activation of the osteoclasts, although an osteoblast-mediated effect of the hormone cannot be ruled out.
A 2020, 'CRISPR disruption and UK Biobank analysis of a highly conserved polymorphic enhancer suggests a role in male anxiety and ethanol intake', Molecular Psychiatry.
Here, we report the localization within embryonic tissues of xWnt6 protein; together with the temporal and spatial expression of Xenopus laevis Wnt6 mRNA. Wnt6 expression in Xenopus embryos is low until later stages of neurulation, when it is predominantly found in the surface ectoderm. Wnt6 expression increases during early organogenesis in the epidermis overlaying several developing organs, including the eye, heart, and pronephros. At later stages of development, Wnt6 mRNA and protein generally localize in epithelial tissues and specifically within the epithelial tissues of these developing organs. Wnt6 localization correlates closely with sites of both epithelial to mesenchymal transformations and mesenchymal to epithelial transformations. Xenopus Wnt6 sequence and its expression pattern are highly conserved with other vertebrates. Xenopus embryos, therefore, provide an excellent model system for investigating the function of vertebrate Wnt6 in organ development and regulation of tissue architecture. Developmental Dynamics 237:768 -779, 2008.
Neuromedin-U (NMU) has been reported to drive several physiological or behavioural responses following i.c.v. injection of the peptide into the third ventricle of rodent brains. Many of these responses are mediated through a change in corticotrophin-releasing factor (CRF) output from the paraventricular nucleus (PVN). A number of the physiological or behavioural responses are regulated in a circadian manner, e.g. feeding. We have previously reported NMU gene expression in the suprachiasmatic nucleus (SCN) and NMU-2 receptor expression in the PVN, dorsal medial hypothalamus (DMH) and other regions of the mouse brain. We therefore hypothesized that NMU would be regulated by the circadian clock and may consequently drive a circadian rhythm of CRF expression in the PVN. Here we report that NMU is regulated in a circadian manner with peak expression during the light phase of a light-dark cycle. In C3H mice held in constant darkness, the NMU rhythm free runs with a period predicted by the free running period of locomotor activity in this mouse. The NMU mRNA transcript colocalizes with cells expressing AVP in the SCN and shows a coincident rhythm of expression with AVP. On the other hand, CRF did not express a circadian rhythm of expression in a light-dark cycle, although a rhythm was evident in constant darkness with a peak of expression prior to the rise of NMU in the same conditions. This would suggest that the circadian rhythm in NMU expression in the SCN does not drive a circadian rhythm in CRF in the PVN to be translated into physiological and behavioural responses mediated by NMU.
Running Title; CRISPR analysis of an enhancer controlling ethanol intake.
Siberian hamsters develop hypophagia and increase catabolism of fat reserves in response to short photoperiods resulting in a natural loss of body weight in winter. We previously found that histamine 3 receptor (H3R) mRNA in the posterior hypothalamus is significantly decreased in short photoperiods. We hypothesized that this lower expression of H3R might contribute to the winter hypophagic state, therefore we examined the effects of the H3R agonist imetit and inverse agonists clobenpropit and thioperamide on food intake. We expressed the Siberian hamster H3R receptor in vitro and confirmed that imetit, clobenpropit and thioperamide are bound specifically, thus validating them as tools to investigate the role of H3R in vivo. Intracerebroventricular administration of histamine decreased food intake in hamsters in the fat summer state. Administration of imetit to hamsters in the lean state increased food intake, whereas administration of inverse agonists decreased food intake, though this was associated with decreased locomotor activity. Both H3R inverse agonists prevented the nocturnal rise in body temperature indicating additional effects on energy expenditure. In summary, our results suggest that increased availability of central histamine or the reduction of H3R activity decrease food intake. These effects are similar to those observed in hamsters in short photoperiods.
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