Effects of bilateral basomedial hypothalamic lesions on feeding, fattiness, and reproductive functions in the White Leghorn hen

Feeding behavior after metergoline or GR-46611 injections into the paraventricular nucleus of the hypothalamus in the pigeon

The present study examined changes in spontaneous behavior of free-feeding pigeons in response to local injections of metergoline (MET, an antagonist of 5-HT(1/2) receptors; 5, 10 and 20 nmol), GR-46611 (GR, a 5-HT(1B/1D) agonist; 0.6 and 6 nmol) or vehicle into the paraventricular hypothalamic nucleus (PVN). When infused into the PVN, MET and GR promptly and reliably elicited feeding at their higher doses, without affecting drinking or non-ingestive behaviors (locomotion, exploration, preening, sleep) during the first hour after injection. Both GR- and MET-evoked ingestive responses were associated only with an increase in feeding duration, with no changes in latency to start feeding. In a second series of experiments, the effective doses of MET (20 nmol) and GR (6 nmol) were injected into other diencephalic areas. This exploratory study revealed that intense feeding responses to both MET and GR local injections are also observed in the n. medialis hypothalami posterioris and in the adjacent n. lateralis hypothalami posterioris (PMH/PLH complex, in the caudoventral hypothalamus) and in the n. magnocellularis preopticus (PPM, in the caudal preoptic region). The behavioral profiles associated with these hyperphagic responses were nucleus-specific: in the PMH/PLH, MET-induced feeding was accompanied by an increase in total feeding duration and by a reduction in the latency to start feeding, while ingestive responses evoked by MET in the PPM were associated only with an increase in feeding duration (similar to that observed in the PVN experiments). No ingestive effects were observed after intracerebroventricular (ICV, lateral ventricle) injections of MET (10, 30, 100 or 300 nmol), while ICV injections of GR (3, 15 or 30 nmol) increased feeding only at the higher dose [Da Silva RA, De Oliveira ST, Hackl LPN, Spilere CI, Faria MS, Marino-Neto J, Paschoalini MA. Ingestive behaviors and metabolic fuels after central injections of 5-HT1A and 5-HT1D/1B receptors agonists in the pigeon. Brain Res, 2004;1026:275-283]. These data indicate the presence of a tonic inhibitory influence on feeding behavior exerted by 5-HT afferents on these hypothalamic areas, and suggest that these inputs, possibly mediated by non-rodent-type 5-HT1D/1B receptors, can affect both satiety and satiation mechanisms.

Cloning and expression of zebra finch (Taeniopygia guttata) steroidogenic factor 1: overlap with hypothalamic but not with telencephalic aromatase

The zebra finch (Taeniopygia guttata) brain is highly sexually dimorphic. The organization and production of sex-specific song is considerably influenced by estrogens and androgens. Because the brain itself expresses several steroidogenic enzymes, the local production of sex steroids may contribute to sex differences in neural development. Sex steroid production in gonads is directed by a master regulatory factor, steroidogenic factor 1 (SF1). We have identified a cDNA encoding the homologue of SF1 in the zebra finch and utilized reverse transcription-polymerase chain reaction and in situ hybridization to examine early and late developmental expression of SF1 in brain and in early gonadal development. We found that SF1 is expressed early in embryonic development in the Rathke pouch, beginning at stage 15 and extending to at least stage 27 in both males and females. The earliest expression of SF1 in gonads was found at stage 17 for both males and females and extended to at least stage 27. In brain, we assessed SF1 mRNA expression in posthatch and adult telencephalon, and we compared SF1 and aromatase mRNA expression in adult hypothalamus. In the telencephalon and hippocampus, aromatase was expressed independently of SF1, whereas in the hypothalamus, aromatase and SF1 expression were more closely associated. Expression of SF1 and of aromatase overlapped in restricted regions of the hypothalamus, suggesting that SF1 may regulate aromatase expression in these regions. These findings suggest that steroidogenesis in the zebra finch brain may be regulated by both SF1-dependent and SF1-independent mechanisms. No sex differences were detected in SF1 expression in brain.

Role of the ventromedial hypothalamus in prolactin-induced hyperphagia in ring doves

Prolactin (PRL) strongly stimulates feeding activity and body weight gain in ring doves, and of the brain loci tested to date, the ventromedial hypothalamus (VMH) is the most effective site of PRL action in promoting these changes. To determine if the VMH is essential for this response, we examined the effects of VMN destruction on spontaneous feeding and on changes in food intake induced by intracerebroventricular (i.c.v.) injections of PRL. Male birds were selectively destroyed by radiofrequency lesions (n = 6). A group of sham-lesioned males (n = 6) served as controls. Lesioned birds exhibited a transient increase in food intake that peaked around the seventh postoperative day and declined to baseline levels by day 12. In contrast to this pattern, body weights of lesioned birds increased in parallel with food intake, but remained elevated throughout the 3-week postoperative period. During the peak period of hyperphagia in the lesioned group, food intake and body weight increases were two to three times greater in lesioned birds than in controls. After postoperative feed intake had stabilized, each bird received 5 daily i.c.v. injections of ovine PRL. Food intake and body weight increased dramatically in both groups in response to PRL treatment, and no group differences were observed in response to magnitude. We conclude that VMH destruction strongly perturbs feeding and body weight regulation in doves. However, VMH integrity is not essential for the expression of PRL-induced hyperphagia.

Neural sites and pathways regulating food intake in birds: a comparative analysis to mammalian systems

The paper reviews hypotheses explaining the regulation of food intake in mammals that have addressed specific anatomical structures in the brain. An hypothesis, poikilostasis, is introduced to describe multiple, homeostatic states whereby the regulation of metabolism and feeding occur in birds. Examples are given for both wild and domestic avian species, illustrating dynamic shifts in homeostasis responsible for the changes in body weights that are seen during the course of an annual cycle or by a particular strain of bird. The following neural structures are reviewed as each has been shown to affect food intake in birds or in mammals: ventromedial hypothalamic nucleus (n.), lateral hypothalamic area, paraventricular hypothalamic n., n. tractus solitarius and area postrema, amygdala, parabrachial n., arcuate n. and bed n. of the stria terminalis. Two neural pathways are described which have been proposed to regulate feeding. The trigeminal sensorimotor pathway is the most complete neural pathway characterized for this behavior and encompasses the mechanics of pecking, grasping and mandibulating food particles from the tip of the bill to the back of the buccal cavity. A second pathway, the visceral forebrain system (VFS), affects feeding by regulating metabolism and the balance of the autonomic nervous system. Wild, migratory birds are shown to exhibit marked changes in body weight which are hypothesized to occur due to shifts in balance between the sympathetic and parasympathetic nervous systems. Domestic avian species, selected for a rapid growth rate, are shown to display a dominance of the parasympathetic nervous system. The VFS is the neural system proposed to effect poikilostasis by altering the steady state of the autonomic nervous system in aves and perhaps is applicable to other classes of vertebrates as well.

The effect of monochromatic light on broiler growth and development

Artificial illumination, including light quality, is crucial in modem broiler management. In the present study, a new, highly efficient, monochromatic light system has been developed for broilers. One hundred and eighty male broiler chicks (Anak) were divided into four light treatment groups (n = 45) in three replicates each. All birds were housed in a single room previously divided by wooden bars into 12 sealed cells of 1 m2. Feed and water were provided for ad libitum consumption. Light intensity was 0.1 W/m2 at the height of birds' heads and was scheduled for 23 h of light and 1 h of dark during the entire experimental period. Light treatments were: control white (mini-incandescent light bulbs), blue (480 nm), green (560 nm), and red (660 nm). Body weight was recorded periodically, feed consumption was measured daily, and feed efficiency was calculated. Blood samples were taken at 1, 9, and 32 d of age and plasma testosterone was determined. Two necropsies were conducted, at 23 and 35 d of age, and selected glands and organs were weighed. In the group reared under green light, a significant enhancement in weight gain was observed as early as 3 d of age; this gain was maintained during the entire experimental period. Broilers reared under blue light had a later onset of growth enhancement and were significantly heavier than those reared under white and red light at 20 d of age. Plasma testosterone levels were significantly higher in birds reared under blue light. Breast muscle weights were significantly higher in the birds reared under green light at 23 and 35 d of age. These results suggest that green and blue light stimulate growth.

Leptin receptor mRNA is expressed in ewe anterior pituitary and adipose tissues and is differentially expressed in hypothalamic regions of well-fed and feed-restricted ewes

Infertility associated with suboptimal nutrition is a major concern among livestock producers. Recently, much effort has been put into understanding the role of the protein leptin in regulating feed intake and reproduction. Leptin, produced by adipocytes, has receptors in the hypothalamus, but more precise locations of leptin receptor-expressing cell bodies have not been reported in a livestock species. The leptin receptor transcript has several splice variants in the mouse and human, but only the "long-form" product (OBRL) is capable of signal transduction. A partial ovine long-form leptin receptor cDNA was cloned and used to evaluate OBRL mRNA expression within hypothalamic, anterior pituitary, and adipose tissues of ovariectomized adult ewes. Expression was detected in reverse transcription-polymerase chain reaction products of all tissues examined. OBRL mRNA was detected by in situ hybridization in the ventromedial and arcuate nuclei of the hypothalamus. In ewes that had been feed restricted for 3 wk before tissue collection, the expression of OBRL mRNA in these areas was greater (P < 0.05) than that found in well-fed ewes. These findings provide evidence that the full-length leptin receptor is expressed in hypothalamic, anterior pituitary, and adipose tissue (the latter proffering an autoregulatory mechanisms for leptin) and that within the hypothalamus, this receptor form is differentially expressed in well-fed vs. feed-restricted animals.

Hypothalamic obese, functionally castrated hens are hypersensitive to estrogenic modulation of lipid metabolism

Estradiol benzoate (E2) increases plasma lipids in hypothalamic obese, functionally castrated (OFC), obese laying (OL), and control laying hens (CONT). However, E2 reduces fattiness in OFC but not in OL or CONT hens. Antiestrogen, such as tamoxifen (TAM), reduces plasma lipids in OL and CONT, but not in OFC, hens and has no effect on fattiness in any of them. Apolipoprotein VLDL-II (apo-VLDL-II), lipoprotein lipase (LPL), and rate of lipolysis may mediate these estrogenic effects. In the present study, effects of E2 and TAM on fattiness, plasma apo-VLDL-II, in vitro lipolysis, and LPL activity in postheparin plasma and abdominal adipose tissue (AAT) were determined in OFC, OL, and CONT hens. Basomedial hypothalamic lesions were performed in 3-month-old White Leghorn hens. At the static phase, 10 months later, OFC OL, and CONT hens were divided into three subgroups and injected IM on alternate days, with either 2 mg E2/kg b.wt., 10 mg TAM/kg, or vehicle corn oil, for 5 weeks. In OL and OFC hens, body and AAT weights were higher than in CONT poullets. Food intake and ovarian weight were similar in OL and CONT, higher than in OFC hens. Plasma LPL activity was higher, whereas plasma apo-VLDL-II and stimulated lipolysis were lower in OFC than in OL and CONT hens. In OFC hens LPL activity per unit of AAT was half than in OL and CONT. Total LPL activity in AAT was similar in OFC and CONT and higher in OL hens. Levels of basal lipolysis were similar in all experimental hens. TAM did not affect any of the measured parameters in OFC hens. In OL and CONT hens, TAM depressed apo-VLDL-II, increased plasma LPL activity, but had no effects on AAT LPL activity, on stimulated lipolysis, or fattiness. E2 increased apo-VLDL-II to similar levels in all groups and reduced LPL activity in plasma and AAT of obese hens. Only in OFC hens did E2 enhance basal and stimulate lipolysis and reduce FI and fattiness. We conclude that in adult laying hens, unlike in cockerels and juvenile hens, estrogen reduces lipid incorporation in fat depots by enhancing apo-VLDL-II production that reduces plasma and AAT LPL activity. This may increase lipoprotein available for incorporation into developing yolks. The lack of estrogen in OFC hens reduces circulating apo-VLDL-II and thus increases LPL activity and amount of fat depots.

Effects of estradiol and tamoxifen on feeding, fattiness, and some endocrine criteria in hypothalamic obese hens

In White Leghorn hens, basomedial hypothalamic (BMH) lesions result in two syndromes: a) obese, functionally castrated (OFC) hens, in which both the ventromedial hypothalamic nucleus (VMH) and the mammillary nuclei are damaged and plasma estrogen is very low; and b) obese laying (OL) hens, which have normal levels of plasma estrogen and are less obese than the former, and whose lesion is limited to the VMH. In the present study, the involvement of estrogen in regulation of fattiness and energy metabolism was assayed in OFC, OL, and control (CONT) hens. BMH lesions were made at 13 weeks of age. When the typical syndromes reached the static phase, 20 weeks later, CONT, OFC, and OL hens were divided into three subgroups and were injected for 10 weeks on each alternate day, with either 10 mg tamoxifen (TAM)/kg, 2 mg estradiol benzoate (E2)/kg, or the vehicle, corn oil (0.5 ml). E2 raised plasma total lipids and reduced plasma glucose, insulin, and hematocrit in all treated hens, and increased liver weight in OL and OFC, but not in CONT hens. In OFC hens only, E2 reduced food intake (FI) and fattiness. In OL and CONT hens, E2 increased plasma T3, but raised the resting metabolic rate (RMR) only in CONT ones. In OFC hens, E2 reduce plasma T3 and T4 without affecting RMR. E2 reduced comb weight and egg production in CONT and more severely in OL hens. In the latter, E2 diminished ovarian and oviduct weights, whereas in OFC hens it increased the size of the atrophied oviduct. TAM had no visible effect on OFC hens.(ABSTRACT TRUNCATED AT 250 WORDS)