Cyclic feeding behaviour and changes in hypothalamic galanin and neuropeptide Y gene expression induced by zinc deficiency in the rat.

Dietary zinc-deficiency induces a striking reduction and a cyclic pattern of food intake in rodents. To elucidate the mechanisms for these effects, we studied the hypothalamic content, synthesis, and distribution of galanin (GAL) and neuropeptide Y (NPY) during zinc deficiency and refeeding in the rat. In Wistar rats, three weeks of zinc-deprivation consistently induced a reduction and a cyclic pattern of night- and day-time food intake, as well as of water intake. This was accompanied in zinc-deficient (ZD) rats, and to a lesser extent in pair-fed (PF) rats, by a decrease of hypothalamic GAL mRNA concentration (CTR: 100 +/- 8, ZD: 61 +/- 4, PF: 78 +/- 2 arbitrary densitometric units, ADU, P < 0.01) and an increase of hypothalamic NPY (CTR: 100 +/- 11, ZD: 154 +/- 10, PF: 126 +/- 4 ADU, P < 0.05), without peptide modification. The two neuropeptidergic systems were not affected by the cycles of feeding, with the exception of the NPY-immunoreactivity in the suprachiasmatic nuclei (geniculo-hypothalamic tract), that was inversely correlated to the food intake in both ZD and PF animals. In a second experiment, we showed that zinc-repletion for 4 days suppressed the behaviour induced by a two-week zinc-deprivation, and reversed the increase of NPY mRNA in ZD animals. We finally demonstrated that zinc-deficiency induced a similar behaviour in Zucker rats. However, in these rats whose synthesis of NPY is constitutively up-regulated, no change of NPY synthesis was observed in ZD rats, suggesting that the increase observed in Wistar is adaptative rather than instrumental to the abnormal food intake. In conclusion, we have further characterized the cyclic feeding behaviour of the zinc-deficient Wistar rats, and shown in these animals a decreased activity of the GAL system and an increased activity of the NPY system, likely corresponding to a compensatory response of the two neuropeptidergic systems, as observed in food-deprived animals. As spontaneous food intake of ZD rats does not increase, a resistance to NPY could also be present. These behavioural and neuropeptidergic changes were partially reversed by reintroduction of zinc in the diet. In Zucker rats, the same behaviour occurred despite an insensitivity of the NPY system to the zinc-deficiency. In addition, we describe a nutritional regulation of the NPY-immunoreactivity in the geniculo-hypothalamic tract, that could constitute the substrate of circadian rhythm modulation by timed feeding.

Sex-steroid control of galanin in the rat hypothalamic-pituitary axis.

To further investigate how sex steroids regulate galanin (GAL) in the rat pituitary and hypothalamus, we examined the effects of prepubertal gonadectomy (Gx) and long-term (9 weeks) replacement with estradiol (E2) or testosterone (T) on pituitary and hypothalamic GAL concentrations in Wistar rats (5-6/group). Sham-operated animals served as controls (CTR). Pituitary GAL concentration was markedly higher in random-cycling CTR-females than in CTR-males (1391 +/- 247 vs 39 +/- 5 pg/mg protein, P < 0.01) and decreased after Gx only in females (20 +/- 3 pg/mg protein, P < 0.01). E2 strongly increased pituitary GAL in Gx-females and Gx-males (4470 +/- 365 and 3853 +/- 347 pg/mg protein, P < 0.01), whereas T had no effect. Inversely, hypothalamic GAL was higher in CTR males than in CTR females (5.4 +/- 0.3 vs 4.0 +/- 0.5 ng/mg protein, P < 0.05), and decreased significantly after gonadectomy in males (3.7 +/- 0.2 ng/mg protein, P < 0.01). The only steroid treatment that significantly modified hypothalamic GAL in Gx animals was administration of E2 to females (5.7 +/- 0.4 ng/mg protein, P < 0.01 vs non-treated Gx). We also studied in hypophysectomized (Hx) rats (8/group) the effects of sex steroids on hypothalamic GAL concentration and distribution. The low hypothalamic GAL concentration observed in male and female Hx rats (1.0 +/- 0.1 ng/mg protein) was significantly increased by T in males and in females (respectively, by 40% and by 50%, P < 0.02) and by E2 in males (by 60%, P < 0.02).(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of the endothelin-1 gene in the rat thyroid gland and changes in its peptide and mRNA levels in goiter formation and iodide-induced involution.

Endothelin-1 (ET-1) is a major vasoconstrictor peptide, first found in endothelial cells, and later in many other tissues, including the thyroid gland. We analysed the expression of the ET-1 gene in the rat thyroid gland and changes in ET-1 mRNA and peptide levels in goiter development and involution, two circumstances characterised by vascular changes. Thyroid hyperplasia was induced in adult Wistar rats by feeding a low iodine diet (LID) supplemented with 0.25% thiouracil for 10 days, and LID alone for 2 further days (H.12 group). Involution was induced by injecting 100 micrograms iodide and refeeding a normal diet during 6 h, 12 h, and 24 h (I.6h, I.12h, I.24h groups). Rats fed a normal iodine diet were used as controls. A specific 488 bp cDNA corresponding to the known sequence of pre-pro ET-1 was found by RT-PCR from RNA extracts in all thyroid experimental groups, as well as in lung and kidney which were used as positive controls. RP-HPLC analysis showed that ET-1 immunoreactivity eluted similarly as mature ET-1. During hyperplasia, ET-1 mRNA and peptide levels were increased 3.5- and 5-fold respectively. The relative volume of the vascular bed was more than doubled. During iodide-induced involution, the glandular ET-1 mRNA level remained elevated. The concentration of ET-1 peptide increased and was significantly greater at 12 h involution than in the H.12 group. At this time, the capillary reticulum reverted to individual capillaries and the vascular bed was significantly reduced. These data demonstrate that the ET-1 gene is expressed in the rat thyroid gland and that the ET-1 mRNA and peptide levels are increased during thyroid hyperplasia and remain elevated during a phase of rapid iodide-induced involution. These data suggest that changes in ET-1 production may play a role in control of thyroid gland trophic regulation and vascularity.

Pituitary-dependent hormonal regulation of galaninergic neurons in the rat hypothalamus.

To investigate whether pituitary-dependent hormones may regulate galanin (GAL) content, synthesis and distribution in the hypothalamus, female hypophysectomized Wistar rats were treated for 2 weeks with subcutaneous injections of thyroxine (T4, 2 x 1 microgram), bovine growth hormone (GH, 2 x 125 micrograms), cortisol (C, 50 micrograms), subcutaneous implants of beta-estradiol (E2, 5-mm implant, dilution 1:1), or with the combinations [T4+GH], [T4+GH+C+E2] or [T4+GH+C+E2 + rat PRL, 2 x 125 micrograms] (doses/100 g BW/day). Concentrations of GAL in the hypothalamus were measured by radioimmunoassay (RIA) and GAL mRNA abundance was quantified by Northern blot (6 rats/group); 2 rats/group were used for immunohistochemistry. Hypophysectomy caused decreases of hypothalamic GAL peptide and mRNA concentrations (by 70 and 50%, respectively; p < 0.05 vs. intact rats). GAL immunoreactivity disappeared in the median eminence (ME), but increased in the neurohypophyseal magnocellular neurons of hypophysectomized rats. Substitution with T4, GH, [T4+GH], C or E2 had no significant effect on total hypothalamic GAL peptide and GAL mRNA concentrations. A treatment combining [T4+GH+C+E2] increased hypothalamic GAL (1.9 +/- 0.1 vs. 1.2 +/- 0.1 ng/mg protein in untreated hypophysectomized rats; p < 0.01) and GAL mRNA concentrations (127 +/- 19 vs. 59 +/- 2 densitometric units in untreated rats, p < 0.001). Addition of PRL to this combined treatment had no further effect. Treatment with T4, GH, [T4+GH] or E2 enhanced GAL labeling in the ME of hypophysectomized rats. The effect of estrogens was restricted to the GnRH-rich lateral regions of the ME. The combined treatment with [T4+GH+C+E2] restored the ME GAL immunoreactivity to levels observed in intact rats. In contrast, the increased GAL labeling observed in magnocellular neurons after hypophysectomy was not influenced by any hormonal treatment. In conclusion, hypophysectomy leads to marked reductions of hypothalamic GAL and GAL mRNA concentrations, and of GAL immunoreactivity in the ME. These reductions are prevented in part by a combined hormonal treatment associating T4, GH, C and E2, but not by any hormone given alone. This suggests specific pituitary hormone-dependent regulation of the hypophysiotropic GAL neurons. In contrast, the increased GAL labeling in magnocellular neurons of hypophysectomized rats persists despite hormonal treatment and likely represents a lesional effect on the neurohypophyseal GAL system.

Effects of hypophysectomy on galaninergic neurons in the rat hypothalamus.

To understand better the relationship between hypothalamic galaninergic neurons and the pituitary gland, we studied the effects of hypophysectomy on hypothalamic galanin (GAL) content and distribution by radioimmunoassay and immunohistochemistry, and on GAL mRNA by Northern blot analysis. Three weeks after hypophysectomy, performed at 5 or 8 weeks of age, the hypothalamic concentrations of GAL and GAL mRNA were reduced by 30-50% in both male and female rats, compared to age- and sex-matched controls. Similar reverse-phase HPLC retention times of hypothalamic GAL were observed in intact and hypophysectomized rats. The reduction of hypothalamic GAL concentration following hypophysectomy was time-dependent, as peptide levels were unaffected one week after surgery. Immunohistochemistry showed regional differences in the effect of hypophysectomy on galaninergic neurons. In the hypophysiotropic hypothalamus, the scarce GAL immunoreactivity normally observed in the arcuate nuclei was no longer detectable in hypophysectomized rats, and the intense GAL immunoreactivity of the external zone of the median eminence progressively decreased and completely disappeared 3 and 6 weeks after hypophysectomy. In contrast, in the neurohypophyseal system, there was an increase of GAL labelling of the perikarya and emerging axons in the supraoptic and lateral-paraventricular nuclei, 1 and 3 weeks after hypophysectomy, that disappeared 6 weeks after hypophysectomy. An increase of GAL immunoreactivity was also observed in the internal zone of the median eminence 1 week but not 3 weeks after hypophysectomy. We conclude that hypophysectomy reduces the content of GAL and GAL mRNA in the rat hypothalamus. These changes are time-dependent and clearly detected after 3 weeks. The neurohypophyseal and hypophysiotropic galaninergic systems respond differently to hypophysectomy.(ABSTRACT TRUNCATED AT 250 WORDS)

[Neuroendocrine regulation of eating behavior]. / La régulation neuroendocrine du comportement alimentaire.

We review current neuroendocrine concepts about feeding behavior. Digestive or metabolic inputs are conveyed to the hypothalamus by endocrine and neuroendocrine pathways (insulin, cholecystokinin). The hypothalamus regulates feeding behavior both quantitatively and qualitatively through several neuroendocrine mediators (neuropeptide Y, galanin, GHRH...). The hypothalamus also integrates, by its communicative network, inputs from the cortex, the sub-cortex, the peripheral metabolism and it modifies consequently the feeding behavior. These neuroendocrine models are developed from many experimental observations both in normal and obese animals.