Oestradiol and diet modulate energy homeostasis and hypothalamic neurogenesis in the adult female mouse.

Leptin and oestradiol have overlapping functions in energy homeostasis and fertility, and receptors for these hormones are localised in the same hypothalamic regions. Although, historically, it was assumed that mammalian adult neurogenesis was confined to the olfactory bulbs and the hippocampus, recent research has found new neurones in the male rodent hypothalamus. Furthermore, some of these new neurones are leptin-sensitive and affected by diet. In the present study, we tested the hypothesis that diet and hormonal status modulate hypothalamic neurogenesis in the adult female mouse. Adult mice were ovariectomised and implanted with capsules containing oestradiol (E2 ) or oil. Within each group, mice were fed a high-fat diet (HFD) or maintained on standard chow (STND). All animals were administered i.c.v. 5-bromo-2'-deoxyuridine (BrdU) for 9 days and sacrificed 34 days later after an injection of leptin to induce phosphorylation of signal transducer of activation and transcription 3 (pSTAT3). Brain tissue was immunohistochemically labelled for BrdU (newly born cells), Hu (neuronal marker) and pSTAT3 (leptin sensitive). Although mice on a HFD became obese, oestradiol protected against obesity. There was a strong interaction between diet and hormone on new cells (BrdU+) in the arcuate, ventromedial hypothalamus and dorsomedial hypothalamus. HFD increased the number of new cells, whereas E2 inhibited this effect. Conversely, E2 increased the number of new cells in mice on a STND diet in all hypothalamic regions studied. Although the total number of new leptin-sensitive neurones (BrdU-Hu-pSTAT3) found in the hypothalamus was low, HFD increased these new cells in the arcuate, whereas E2 attenuated this induction. These results suggest that adult neurogenesis in the hypothalamic neurogenic niche is modulated by diet and hormonal status and is related to energy homeostasis in female mice.

Developmental aspect of the gonadotropin-releasing hormone system.

Gonadotropin-releasing hormone (GnRH) regulates the hypothalamo-pituitary-gonadal (HPG) axis in all vertebrates studied. GnRH neurons that regulate the HPG axis are primarily derived from progenitor cells in the nasal compartment (NC) and migrate along olfactory system derived fibers across the cribriform plate to destinations in the forebrain. Across their long and uncommon migratory route many factors are likely important for their successful development. Several classes of molecules are being studied for their potential influences on migration, including those related to cell surface interactions (membrane receptors, adhesion molecules, extracellular matrix (ECM) molecules, etc.) and those related to communication across distances (neurotransmitters, peptides, chemoattractant or repellent molecules). Of the classes of molecules associated with cell surface interactions, glycoconjugates with terminal galactose, are temporally and spatially expressed on olfactory fibers that guide GnRH neurons and may play role(s) in migration. Of the molecules associated with communication across distances, the neurotransmitter gamma-aminobutyric acid (GABA) is associated with the GnRH migration pathway and influences the position and organization of GnRH neurons in vitro and in vivo. Furthermore, galactose-containing glycoconjugates and GABA are associated with GnRH neurons in species ranging from humans to lamprey. In mice and rats, GABA is found transiently within a subpopulation of GnRH neurons as they migrate through the NC. One of the key elements in considering regulators of GnRH neuron migration is the diversity of GnRH synthesizing cells. For example, only subpopulations of GnRH neurons also contain GABA, specific GABA receptors, or select glycoconjugates. Similarly, treatments that influence GnRH neuronal migration may only affect specific subsets and not the entire population. It is likely that we will not be able to characterize the migration of all GnRH neurons by a single factor. By combining molecular inquiries with genetic models, single cell analyses, and an in vitro migration model, we are beginning to decipher one of the most critical events in the establishment of the reproductive axis.

Deleted in colorectal cancer (DCC) regulates the migration of luteinizing hormone-releasing hormone neurons to the basal forebrain.

Luteinizing hormone-releasing hormone (LHRH) neurons migrate from the vomeronasal organ (VNO) to the forebrain in all mammals studied. In mice, most LHRH neuron migration is dependent on axons that originate in the VNO but bypass the olfactory bulb and project into the basal forebrain. Thus, cues that regulate the trajectories of these vomeronasal axons are candidates for determining the destination of LHRH neurons. Using in situ hybridization techniques, we examined the expression of Deleted in colorectal cancer (DCC), a vertebrate receptor for the guidance molecule netrin-1, during development of the olfactory system. DCC is expressed by cells in the olfactory epithelium (OE) and VNO, and in cells migrating from the OE and VNO from embryonic day 11 (E11) to E14. Some DCC(+) cells on vomeronasal axons in the nose also express LHRH. However, DCC expression is downregulated beginning at E12, so few if any LHRH neurons in the forebrain also express DCC. In rat, DCC is expressed on TAG-1(+) axons that guide migrating LHRH neurons. We therefore examined LHRH neuron migration in DCC(-/-) mice and found that trajectories of the caudal vomeronasal nerve and positions of LHRH neurons are abnormal. Fewer than the normal number of LHRH neurons are found in the basal forebrain, and many LHRH neurons are displaced into the cerebral cortex of DCC(-/-) mice. These results are consistent with the idea that DCC regulates the trajectories of a subset of vomeronasal axons that guide the migration of LHRH neurons. Loss of DCC function results in the migration of many LHRH neurons to inappropriate destinations.

Effects of gamma-aminobutyric acid(A) receptor manipulation on migrating gonadotropin-releasing hormone neurons through the entire migratory route in vivo and in vitro.

GnRH neurons originate in the nasal compartment and migrate along vomeronasal fibers over the cribiform plate to the forebrain. Previously, we found gamma-aminobutyric acid (GABA) present in GnRH neurons during development. To clarify the influence of GABA across the entire GnRH migration route, we examined the effects of muscimol and bicuculline (GABA(A) agonist and antagonist) in vivo and in vitro, maintaining the integrity of the nasal-forebrain connection. For in vivo experiments, mice were administered muscimol, bicuculline, or vehicle on days 10-15 of pregnancy and were killed on embryonic day 15 (E15). For in vitro experiments, 250-microm parasagittal slices of whole heads of E13 mice were incubated with muscimol, bicuculline, or vehicle for 2 days. Muscimol inhibited GnRH cell migration and decreased extension of GnRH fibers. Bicuculline treatment led to a disorganized distribution of GnRH cells in the forebrain and a concomitant dissociation of GnRH cells from fibers of guidance. These results suggest that GABA's influence on GnRH development changes as the cells move out of the nasal compartment and extend processes toward the median eminence.

The effects of gonadal steroids on brain stimulation reward in female rats.

The present study examined possible estrogen and/or progesterone effects on the mesolimbic dopamine (DA) system using brain stimulation reward (BSR). It is well known that BSR with electrical stimulation of the medial forebrain bundle (MFB) depends on the functioning of the mesolimbic DA system. If estrogen affects this system in a manner similar to its effects on the nigrostriatal DA system, reward measures would be expected to vary across the estrous cycle. Cycling female rats were trained to bar press for electrical stimulation to the MFB. Animals were tested at each stage of the estrous cycle, after ovariectomy and 4, 24, 48, 72 and 96 h after hormone replacement with estradiol (10 micrograms, s.c.), estradiol and progesterone (0.5 mg, s.c.), or oil (s.c.). The rewarding value of the stimulation and the maximum rate of bar pressing increased during estrus, but not during proestrus or metestrus, as compared with diestrus. Hormone replacement had differing effects on reward and motor performance. Motor performance increased 4 and 24 h after estrogen alone and 24 h after estrogen with the addition of progesterone 4 h before testing. The rewarding value of the stimulation increased only 24 h after estrogen together with an injection of progesterone 4 h before testing. These results indicate that gonadal steroids affect the functioning of the mesolimbic DA system.

Investigation of the effects of opiate antagonists infused into the nucleus accumbens on feeding and sucrose drinking in rats.

Previous work has shown that opiate agonist infusion into the nucleus accumbens, a region implicated in reinforcement, stimulates food intake. In the present study, the effects of opiate antagonist infusion into this region were examined in two behavioral paradigms. In the feeding test, food-deprived animals were tested for intake of laboratory chow. In the sucrose intake test, sated animals familiar with a 20% sucrose solution were tested. Before these tests, the following drugs were bilaterally infused into the accumbens: naloxone (0, 1, 10 and 30 micrograms; equivalent to 2.8, 28 and 83 nmol, respectively), naltrexone (0, 0.2, 2 and 20 micrograms; 0.55, 5.5 and 55 nmol, respectively), beta-funaltrexamine (0 and 15 micrograms; 31 nmol), naloxonazine (0 and 10 micrograms; 15 nmol), naltrindole (trial 1: 0, 1, 10 and 20 micrograms; 2.2, 22 and 44 nmol, respectively; trial 2: 0, 0.1 and 0.5 micrograms; 0.22 and 1.1 nmol, respectively) and nor-binaltorphimine (0, 0.1, 1 and 10 micrograms; 0.14, 1.4 and 14 nmol, respectively). Naloxone and naltrexone both significantly reduced sucrose drinking and did not affect feeding. Naloxone infused into the dorsolateral striatum, as a control, had no effect on sucrose drinking. Accumbens infusion of the mu antagonist beta-funaltrexamine reduced both sucrose drinking and feeding. The mu 1 antagonist naloxonazine did not influence intake behaviors, with the exception of a decrease in duration of chow feeding. In contrast, the delta antagonist naltrindole markedly potentiated both sucrose drinking and duration of chow feeding. In a replication of this effect, systemic naltrexone given concurrently blocked the enhancement. The kappa antagonist nor-binaltorphimine did not influence any parameters of ingestive behavior. Although some treatments also decreased motor activities, the overall profile of behavior suggested specific effects on ingestive behavior. The putative contributions of mu and delta receptors within the nucleus accumbens to modulation of food reward are discussed.