Leptin, a newly-discovered hormonal product of the obese (ob) gene, is expressed by adipocytes and thought to play a role in the regulation of food intake and metabolism. We tested the hypothesis that leptin signals metabolic information to the reproductive system by examining its effects on the reproductive system of ob/ob mice, which have a congenital deficiency in leptin and are infertile. We treated pair-fed males and females with leptin (50 microg twice daily, ip) or vehicle (n=10/group) for 14 days, after which the animals were bled and killed. Leptin-treated females had significantly elevated serum levels of LH, increased ovarian and uterine weights, and stimulated aspects of ovarian and uterine histology compared to controls. Leptin-treated males had significantly elevated serum levels of FSH, increased testicular and seminal vesicle weights, greater seminal vesicle epithelial cell height, and elevated sperm counts compared to controls. These results demonstrate that leptin stimulates the reproductive endocrine system in both sexes of ob/ob mice and suggest that leptin may serve as a permissive signal to the reproductive system of normal animals.
Leptin is a protein product of the obese (ob) gene, which is secreted by adipocytes and functions as a satiety factor to regulate food intake. The expression of the leptin receptor in several hypothalamic nuclei suggests that multiple neuronal subtypes are targets for leptin's action. Products of the proopiomelanocortin (POMC) gene are known to affect feeding behavior, and POMC neurons share a similar distribution with leptin receptor mRNA in the arcuate nucleus. We used double label in situ hybridization and computerized image analysis to test the hypothesis that POMC neurons coexpress the leptin receptor. Quantitative analysis confirmed that POMC neurons in the hypothalamus express leptin receptor mRNA. Based on this observation, we infer that POMC neurons and the products of the POMC gene may be part of the signaling pathway mediating leptin's action on feeding and perhaps other physiological functions.
The ventromedial hypothalamus (VMH) is a distinct morphological nucleus involved in feeding, fear, thermoregulation, and sexual activity. It is essentially unknown how VMH circuits underlying these innate responses develop, in part because the VMH remains poorly defined at a cellular and molecular level. Specifically, there is a paucity of cell-type-specific genetic markers with which to identify neuronal subgroups and manipulate development and signaling in vivo. Using gene profiling, we now identify ϳ200 genes highly enriched in neonatal (postnatal day 0) mouse VMH tissue. Analyses of these VMH markers by real or virtual (Allen Brain Atlas; http:// www.brain-map.org) experiments revealed distinct regional patterning within the newly formed VMH. Top neonatal markers include transcriptional regulators such as Vgll2, SF-1, Sox14, Satb2, Fezf1, Dax1, Nkx2-2, and COUP-TFII, but interestingly, the highest expressed VMH transcript, the transcriptional coregulator Vgll2, is completely absent in older animals. Collective results from zebrafish knockdown experiments and from cellular studies suggest that a subset of these VMH markers will be important for hypothalamic development and will be downstream of SF-1, a critical factor for normal VMH differentiation. We show that at least one VMH marker, the AT-rich binding protein Satb2, was responsive to the loss of leptin signaling (Lep ob/ob ) at postnatal day 0 but not in the adult, suggesting that some VMH transcriptional programs might be influenced by fetal or early postnatal environments. Our study describing this comprehensive "VMH transcriptome" provides a novel molecular toolkit to probe further the genetic basis of innate neuroendocrine behavioral responses.
Estrogen-receptor alpha (ERα) neurons in the ventrolateral region of the ventromedial hypothalamus (VMHVL) control an array of sex-specific responses to maximize reproductive success. In females, these VMHVL neurons are believed to coordinate metabolism and reproduction. However, it remains unknown whether specific neuronal populations control distinct components of this physiological repertoire. Here, we identify a subset of ERα VMHVL neurons that promotes hormone-dependent female locomotion. Activating Nkx2-1-expressing VMHVL neurons via pharmacogenetics elicits a female-specific burst of spontaneous movement, which requires ERα and Tac1 signaling. Disrupting development of Nkx2-1+ VMHVL neurons results in female-specific obesity, inactivity, and loss of VMHVL neurons co-expressing ERα and Tac1. Unexpectedly, two responses controlled by ERα neurons, fertility and brown adipose tissue thermogenesis, are unaffected. We conclude that a dedicated subset of VMHVL neurons marked by ERα, NKX2-1, and Tac1 regulates estrogen-dependent fluctuations in physical activity and constitutes one of several neuroendocrine modules that drive sex-specific responses.
Chronic consumption of a fat-rich diet leads to attenuation of leptin signaling in hypothalamic neurons, a hallmark feature of cellular leptin resistance. To date, little is known about the temporal and spatial dysregulation of neuronal function under conditions of nutrient excess. We show that agouti-related protein (AgRP)-expressing neurons precede proopiomelanocortin neurons in developing diet-induced cellular leptin resistance. High-fat diet-induced up-regulation of suppressor of cytokine signaling-3 (SOCS3) occurs in AgRP neurons before proopiomelanocortin and other hypothalamic neurons. SOCS3 expression in AgRP neurons increases after 2 d of high-fat feeding, but reduces after switching to a low-fat diet for 1 d. Consistently, transgenic overexpression of SOCS3 in AgRP neurons produces metabolic phenotypes resembling those observed after short-term high-fat feeding. We further show that AgRP neurons are the predominant cell type situated outside the blood-brain barrier in the mediobasal hypothalamus. AgRP neurons are more responsive to low levels of circulating leptin, but they are also more prone to development of leptin resistance in response to a small increase in blood leptin concentrations. Collectively, these results suggest that AgRP neurons are able to sense slight changes in plasma metabolic signals, allowing them to serve as first-line responders to fluctuation of energy intake. Furthermore, modulation of SOCS3 expression in AgRP neurons may play a dynamic and physiological role in metabolic fine tuning in response to short-term changes of nutritional status.M ost common forms of obesity, including diet-induced obesity, are associated with hyperleptinemia and impairment of leptin signaling in hypothalamic neurons, the hallmark feature of cellular leptin resistance. Suppressor of cytokine signaling-3 (SOCS3), a direct transcriptional product of STAT3, is up-regulated in the hypothalamus of diet-induced obese animals (1, 2). Mice with heterozygous mutation of the Socs3 gene, neuronal, or proopiomelanocortin (POMC)-specific deletion of the Socs3 gene are hypersensitive to leptin and resistant to diet-induced obesity (3-5). Conversely, up-regulation of SOCS3 in POMC neurons of chow-fed mice leads to increased body adiposity (6). In addition, wide-spread up-regulation of SOCS3 has been shown to be associated with neuronal inflammation in diet-induced obese animals (7). Thus SOCS3, which is up-regulated in chronic obesity, is commonly thought to play a pathophysiological role in obesity-associated leptin resistance.Multiple neuronal subtypes in several regions of the hypothalamus, including the arcuate nucleus, ventromedial hypothalamus, dorsomedial hypothalamus, and lateral hypothalamic area, have been implicated in the regulation of energy balance and leptin action (8,9). A number of hypothalamic neurons and extrahypothalamic neurons express functional leptin receptor (10, 11). Among these neurons, POMC and agouti-related protein (AgRP) neurons are two key arcuate neuronal subtypes. POMC and AgRP neu...
The ventromedial nucleus of the hypothalamus (VMH) influences a wide variety of physiological responses. Here, using two distinct but complementary genetic tracing approaches in mice, we describe the development of VMH efferent projections, as marked by steroidogenic factor-1 (SF-1; NR5A1). SF-1 neurons were visualized by Tau-green fluorescent protein (GFP) expressed from the endogenous Sf-1 locus (Sf-1TauGFP) or by crossing the transgenic Sf1:Cre driver to a GFP reporter strain (Z/EGSf1:Cre). Strikingly, VMH projections were visible early, at embryonic (E) 10.5, when few postmitotic SF1 neurons have been born, suggesting that formation of VMH circuitry begins at the onset of neurogenesis. At E14.5, comparison of these two reporter lines revealed that SF1-positive neurons in the ventrolateral VMH (VMHvl) persist in Z/EGSf1:Cre embryos but are virtually absent in Sf-1TauGFP. Therefore, although the entire VMH including the VMHvl shares a common lineage, the VMHvl further differentiates into a neuronal cluster devoid of SF-1. At birth, extensive VMH projections to broad regions of the brain were observed in both mouse reporter lines, matching well with those previously discovered by injection of axonal anterograde tracers in adult rats. In summary, our genetic tracing studies show that VMH efferent projections are highly conserved in rodents and are established far earlier than previously appreciated. Moreover, our results imply that neurons in the VMHvl adopt a distinct fate early in development, which might underlie the unique physiological functions associated with this VMH subregion.
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