Double immunocytochemistry of vasoactive intestinal peptide and cGnRH-I in male quail: photoperiodic effects.

Reproduction in Japanese quail is primarily regulated by photoperiod. Vasoactive intestinal peptide (VIP) has been suggested as a transducer of environmental information, especially photoperiodic cues, to the hypothalamo-pituitary-gonadal axis. To investigate the possible interaction of VIP and the reproductive (gonadotropin-releasing hormone, GnRH) system, double-immunocytochemical staining for VIP and cGnRH-I was conducted in sexually mature male quail held under a long-day photoperiod (16L:8D; LD) and in sexually quiescent males held under a short-day photoperiod (8L:16D; SD). VIP-immunoreactive (ir) cells were found primarily in three locations: lateral septal organ (LSO) in nucleus accumbens (Ac), ventral hypothalamus, and infundibular area. VIP-ir cells in LSO displayed characteristics typical of cerebrospinal fluid (CSF)-contacting cells, and co-existed with cGnRH-I-ir cells and beaded fibers. In contrast, VIP-ir cells in the infundibular area did not co-exist with cGnRH-I-ir structures. The number of visible VIP-ir cells in the infundibular area of SD males was significantly lower than that of LD males, while the number of visible VIP-ir cells in Ac/LSO was not altered by photoperiod. A cluster of cGnRH-I-ir cells in the caudalmost septal area was heavily innervated by VIP-ir fibers, which appeared to contact cGnRH-I-ir cells directly at this location. Both VIP- and cGnRH-I-ir fibers heavily innervated the external layer of the median eminence (ME). These data suggest that Ac/LSO, the caudalmost septal area, and ME are possible sites of interaction between the VIP and the GnRH systems.

Changes in immunoreactivity to anti-cGnRH-I and -II are associated with photostimulated sexual status in male quail.

In sexually active males exposed to long-day (LD) photoperiod, perikarya in the olfactory bulb, lobus parolfactorius, n. accumbens, and preoptic region were immunoreactive (ir) to an antiserum against gonadotropin-releasing hormone (anti-cGnRH-I), and a cluster of ir-perikarya was found in the caudal-most septal area. Ir-perikarya in these brain areas of sexually inactive short-day (SD) males were located within more discrete areas than those in LD brain, which were more scattered in appearance. Absolute cell numbers were similar between LD and SD brains. Ir-fibers in LD brains were mostly in the external median eminence, along the lateral ventricle to septum (especially in and about the n. accumbens), in the septal-preoptic area, along the third ventricle, and at the n. commissure palli. There were fewer ir-fibers in SD brain. Many small dark ring-like ir-structures were found in the hyperstriatum, hippocampus, and n. taeniae. Interpreted as being ir-terminals on non-ir perikarya, these were not observed in SD males. cGnRH-II ir-perikarya were observed in only two areas regardless of reproductive status: (1) ventral to the substantia grisea centralis and caudal to the oculomotor complex, and (2) scattered in and about the lateral hypothalamus. Ir-fibers occurred in the habenular area, hyperstriatum, hippocampus, parahippocampal area, cortex piriformis, and n. taeniae. cGnRH-II ir-fibers occurred in the external median eminence but were less intensely stained than cGnRH-I ir-fibers. These fibers in SD males were similar except in the diencephalon, where scattered swellings were observed. Thus, the appearance and distribution of anti-cGnRH-I and -II ir-structures change with the sexual status of male quail, but changes in immunoreactivity to anti-cGnRH-I appear to be more widespread.

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.