Diane A. Wilkinson

Leptin Immunoreactivity Is Localized to Neurons in Rat Brain

Leptin is secreted from adipocytes and is thought to enter the brain to regulate and coordinate metabolism, feeding behaviour, energy balance and reproduction. It is now clear that there are many additional sites of leptin production, including human placenta, ovary, stomach, skeletal muscle, mammary gland, pituitary gland and brain. In the present work, we employed double-label immunofluorescent histochemistry to establish the neuronal localization of leptin immunoreactivity (IR). To accomplish this, we used the neuron-specific marker NeuN to label cells in the arcuate nucleus (ARC), piriform cortex and hippocampus. In the supraoptic nucleus (SON) and paraventricular nucleus (PVN), we used antisera to oxytocin and vasopressin as neuronal markers. Double labelling revealed leptin IR in neurons of the ARC and piriform cortex. Leptin IR was confined to the nucleus and to distinct perinuclear sites. In contrast, neurons in the CA 2/CA 3 region of the hippocampus showed little nuclear staining. Leptin IR was clustered around the nucleus in these cells. Neurons of the dentate gyrus exhibited both nuclear and perinuclear localization of leptin IR. In the SON/PVN, most oxytocin- and vasopressin-IR neurons also contained leptin IR, often in perinuclear sites. In conclusion, the neuronal, perinuclear localization of leptin IR in rat brain corresponds closely to that of leptin receptor (OB-R) IR, which has also been detected intracellularly. Our observation of leptin IR associated with cell nuclei suggests the existence of an OB-R distinct from the well-described membrane forms.

Developmental regulation of leptin gene expression in rat brain and pituitary

We have previously reported the expression of leptin mRNA and protein in adult rat brain and pituitary gland. We report here the presence of leptin and leptin receptor mRNA in neonatal female rat brain and pituitary using RT-PCR as well as leptin and leptin receptor immunoreactivity in neonatal rat brain. In addition, we describe age-related changes in leptin mRNA expression in female rat brain and pituitary from postnatal day 2 to 28, evaluated using semi-quantitative RT-PCR analysis. Age-related differences in leptin (ob) mRNA levels were tissue-dependent. The most striking developmental changes were noted in the pituitary and cerebral cortex. In the pituitary, ob mRNA levels were maximal during postnatal days 7-14 and fell sharply by postnatal day 22. In cortex, ob mRNA levels were low in neonatal pups (day 2-7) but increased significantly between postnatal days 14 and 28. Leptin mRNA was detectable at postnatal day 2 in hypothalamus and subcutaneous fat. No significant differences in the level of expression were observed between postnatal day 2 and 28. Serum leptin levels were highest at day 7-14 and decreased significantly by day 21-28, coincident with the fall in pituitary leptin expression. The high levels of leptin expression in the neonatal pituitary suggest that this gland may contribute to the circulating leptin levels during early postnatal development, when adipose deposits are minimal. These data indicate that regulation of leptin gene expression in the postnatal period is tissue-dependent, a finding, which suggests that local leptin expression may have important functional significance in the development of the brain-pituitary system.

Leptin receptors are developmentally regulated in rat pituitary and hypothalamus

We have previously reported that leptin is expressed in adult rat brain and pituitary gland, though the role of leptin in these sites has not been determined. Leptin mRNA is developmentally regulated in the brain and pituitary of male and female rats during early postnatal development, suggesting a role in the maturation of the brain-pituitary system. Here, we sought to extend our previous studies by evaluating (1) the ontogeny of leptin receptor mRNA levels in rat brain and pituitary and (2) pituitary leptin protein levels in neonatal and pre-pubertal rats. Pituitary leptin concentration was highest shortly after birth (postnatal day (PD) 4, 25 ng/mg protein) and fell significantly throughout postnatal development and into adulthood (PD 60, 3.5 ng/mg protein; P<0.005) coincident with a decline in pituitary leptin mRNA levels. Significant age-related effects on leptin receptor mRNA levels were also observed in the pituitary and the hypothalamus of male and female rats using semi-quantitative RT-PCR analysis. In the pituitary, the short form (OBRa) mRNA levels were highest in neonatal rats (PD 4) but declined throughout postnatal development (PD 4-22) paralleling the fall in pituitary leptin mRNA and protein levels. The long form (OBRb) mRNA levels were unaffected by age between PD 4 and 22. In contrast, hypothalamic, levels of OBRb mRNA were very low to undetectable shortly after birth (PD 4) and rose significantly between PD 4 and 14/22 while levels of OBRa mRNA were not significantly different between PD 4 and 22. Immunohistochemical detection of leptin receptor immunoreactivity (all forms) revealed the presence of OBR-like protein in pituitary and hypothalamus as early as PD 4. Cortical leptin receptor mRNA levels were similar throughout early postnatal development. No gender-related differences in leptin receptor mRNA levels were noted in brain or pituitary. In conclusion, these data, together with our previous work, indicate that the neonatal pituitary gland expresses leptin and leptin receptors at levels far in excess of those observed in mature rats. The pituitary is thus quite different from adipose tissue, hypothalamus and cerebral cortex, in which neonatal leptin expression is lowest at birth. Since neonatal pituitary leptin receptor expression is also elevated, it is possible that pituitary-derived leptin plays some role in the development of the hypothalamic-pituitary system.

Hypothalamic resistin immunoreactivity is reduced by obesity in the mouse: co-localization with α-melanostimulating hormone

Resistin is a new adipokine expressed in mouse, rat and human adipose tissue. Resistin may be an important link between obesity and insulin resistance, though this controversial view is complicated by the discovery of multiple sites of resistin expression, including human macrophages, placenta and pancreas. In previous studies we demonstrated that the mouse hypothalamo-pituitary system was also a site of resistin production. Pituitary resistin is developmentally regulated, reduced in the ob/ob mouse and severely down-regulated by food deprivation (24 h). An unexpected finding was that hypothalamic resistin mRNA remained unaffected by fasting. The present experiments examined the localization and possible regulation of hypothalamic resistin protein. Using immunohistochemistry we observed a complex network of resistin+ fibres extending rostrally from the arcuate nucleus of the hypothalamus (ARC) to the preoptic area. Labelled cell bodies occurred only in the ARC and in a periventricular region of the dorsal hypothalamus. Hypothalamic resistin immunoreactivity (ir) was unaffected by fasting (48 h) or by a high fat diet, but the periventricular staining was greatly increased in the lactating mouse. Marked reductions in resistin+ fibres were seen in brain tissue from: (a) ob/ob mice, (b) young mice made underweight for their age by raising them in large litters (20 pups per litter) and (c) mice with hypothalamic lesions induced by monosodium glutamate (MSG) or gold thioglucose (GTG). We speculate that the resistin-ir deficit in genetically obese mice, and in severely underweight mice, could be due to low or absent leptin. In contrast, though MSG- and GTG-treated mice have high levels of circulating leptin, in the presence of excessive visceral fat deposits, we hypothesize that damage to the ARC destroys the resistin+ cell bodies. This latter supposition led us to an additional hypothesis, that resistin-ir would be contained in neurons expressing the proopiomelanocortin (POMC) gene. This proved to be correct. Double label immunofluorescence histochemistry revealed that α-MSH-ir, a marker for POMC neurons, was co-localized with resistin-ir. In conclusion, our data reveal a second example of an adipocytokine co-localized with a hypothalamic neuropeptide. We reported previously that leptin was co-localized with oxytocin and vasopressin. RT-PCR analysis confirmed that resistin mRNA is readily detectable in ARC, but further work is required to determine whether the resistin gene is expressed in POMC neurons or if resistin is specifically accumulated by these cells. Nonetheless, our data suggest that the hypothalamus is a target tissue for resistin.

Prolonged estrogen treatment induces changes in opiate, benzodiazepine and β-adrenergic binding sites in female rat hypothalamus

Exposure of the rat brain to estradiol is known to modify certain neurotransmitter binding sites. We have now examined the influence of long-term (3 months) treatment with this steroid. Opiate and benzodiazepine receptors are both elevated in hypothalamus but not in amygdala or cerebral cortex. In contrast, the affinity, but not maximum binding, of hypothalamic beta-adrenergic sites is reduced 5-fold. Our results confirm and extend previous reports that hypothalamic neurotransmitter binding sites are particularly sensitive to estrogen feedback.

Hypothalamic kiss1 mRNA and kisspeptin immunoreactivity are reduced in a rat model of polycystic ovary syndrome (PCOS).

An intact hypothalamic kiss1/kisspeptin/kiss1r complex is a prerequisite for reproductive competence, and kisspeptin treatment could be a practical therapeutic approach to some problems of infertility. One such disorder is polycystic ovarian syndrome (PCOS), a common cause of infertility affecting more than 100 million women. A rodent model of PCOS is the prepubertal female rat treated for a prolonged period with dihydrotestosterone (DHT), which induces many of the metabolic characteristics of the syndrome. We hypothesized that hypothalamic kiss1 mRNA levels, and kisspeptin immunoreactivity (ir), would be abnormal in these rats. Prepubertal female rats were exposed to DHT for 60 days. Rats were killed in two groups: at 26 and 60 days of DHT exposure. Kiss1 mRNA was quantified in hypothalamus, pituitary, ovary and visceral adipose tissue. Separate groups of rats provided brain tissue for immunohistochemical analysis of kisspeptin-ir. At 26 days of DHT exposure, hypothalamic kiss1 mRNA was severely depleted. In contrast DHT had no effect on pituitary kiss1 expression but it significantly increased levels of kiss1 mRNA in fat (+9-fold; p<0.01) and in ovary (+3-fold; p<0.05). At 60days, kiss1 expression had reverted to normal in hypothalamus and ovary but remained elevated in fat (+4-fold; p<0.05). Immunohistochemical analysis revealed that after 26 days of exposure to DHT, kisspeptin-ir was almost completely absent in the arcuate nucleus and a large depletion in kisspeptin +ve fibers was also seen in the paraventricular nucleus, supraoptic nucleus and in the anteroventral periventricular area. At 60 days, despite restored normal levels of kiss1 mRNA, hypothalamic kisspeptin-ir remained depleted in the treated rats. In summary Kiss1 gene expression is differentially affected in various tissues by chronic exposure to dihydrotestosterone in a rat model of polycystic ovary syndrome. In hypothalamus, specifically, kiss1 mRNA, and levels of kisspeptin immunoreactivity, are significantly reduced. Since these rats exhibit many of the characteristics of polycystic ovary syndrome, we suggest that atypical kiss1 expression may contribute to the multiple tissue abnormalities observed in women with this disorder. However, and of some importance, our data do not appear to be consistent with the elevated levels of LH seen in women with PCOS; i.e. reduced levels of hypothalamic kiss1 mRNA and kisspeptin immunoreactivity observed in DHT-treated rats are unlikely to produce elevated LH secretion.

Beta-adrenergic ([3H]CGP-12177) binding to brain slices and single intact pineal glands

We have characterized and quantified the binding of [3H]CGP-12177 to β-adrenergic receptor sites in slices (300 microns) of rat cerebral cortex. The receptors are stereospecific, saturable and of high affinity. Binding of [3H]CGP is readily reversible and demonstrates appropriated drug specificty. This assay method allows the demonstration of isoproterenol-induced down-regulation (internalization) of β-adrenoreceptors. Receptor recycling is observed at 37°C in the absence of β-agonist but can be blocked by low temperature (0°C) or by monensin. β-Adrenoreceptors can also be labeled and quantified in intact, single pineal glands of rat, mouse and hamster. Rat pineals contain approximately 10 times more binding sites than do hamster or mouse pineals and up to 8 times more sites than found in rat cerebral cortex. Rat pineal [3H]CGP binding can be up- and down-regulated but not to the same degree as seen in brain slices. This assay method is simple, rapid and provides new opportunities for the study of other receptor types in intact tissue.

Benzodiazepine receptors in fish brain: [3H]-flunitrazepam binding and modulatory effects of GABA in rainbow trout.

We have identified and partially characterised benzodiazepine binding sites in whole brain membranes of male rainbow trout. In terms of Bmax and KD values trout brain receptors are remarkably similar to those in rat and human brain. The Hill coefficient was 0.98, indicating a single binding site. GABA (10(-4) M) was able to significantly elevate binding of [3H]-FNZ through a change in KD rather than Bmax. This effect was prevented by the GABA receptor antagonist bicuculline methiodide.

The effect of increased cardiac output on luteal phase gonadal steroids: a hypothesis for runners amenorrhea

The beta-adrenergic agonist isoproterenol was infused intravenously for 4 hours during the midluteal phase of the cycle in six normal women. A rapid increase in cardiac output occurred for the entire duration of the isoproterenol infusion and serum estrogen and progesterone levels (but not luteinizing hormone levels) decreased significantly (P less than 0.001) to a nadir of 30% and 50% of baseline levels, respectively, suggesting increased metabolic clearance of the two steroids. We hypothesize that endurance training chronically increases metabolic clearance of gonadal steroids, resulting in abnormal negative and/or positive feedback on the hypothalamic/pituitary axis leading to the menstrual irregularities commonly seen in athletes.

Mu-opioid ([3H]DAGO) binding in slices of rat brain: Inhibition by sodium ions, guanyl-5′-yl imidodiphosphate and by the adrenergic neurotoxins DSP4 and xylamine

We have characterized and quantified the specific binding of the mu-agonist [3H] DAGO to 300 microM slices of hypothalamus and cerebral cortex. The receptors have many of the opioid characteristics previously demonstrated in homogenate assays. Binding is reversible, saturable, stereospecific and of high affinity. The delta-opioids DTLET and DSLET are 36- and 30-fold respectively, less effective than DAGO in competing for the binding site. Assays can be routinely performed in the presence of physiological concentrations of sodium, though in TRIS buffer the affinity and the number of receptors is increased. Protection of the ligand against proteolytic degradation is unnecessary. Unexpectedly, we observed that GppNHp inhibits [3H] DAGO binding to brain slices. This suggests an allosteric modification of the mu-receptor in the membranes of intact cells. The mu-receptors are also blocked by the adrenergic neurotoxins DSP4 and xylamine. This re-emphasizes our contention that care should be exercised in the use of these drugs. The technique is simple, rapid and involves minimal disruption of tissue. It should provide new opportunities for the study of cell surface opioid receptor subtypes in intact tissue.