John A. Proudman

Effects of reproductive status, ovariectomy, and photoperiod on vasoactive intestinal peptide in the female turkey hypothalamus

Vasoactive intestinal peptide (VIP) appears to be a physiologically relevant prolactin (PRL)-releasing factor during the avian reproductive cycle, yet little is known of the factors involved in modulating the hypothalamic concentrations of this neuropeptide. A heterologous chicken VIP radioimmunoassay was developed to examine the effects of reproductive status, ovariectomy, and photoperiod on hypothalamic VIP immunoreactivity in the female turkey. VIP concentrations were highest in the median eminence/infundibular nuclear complex (ME/INF) relative to other subregions of the hypothalamus and changed only in this region during the reproductive cycle. Quiescent, nonphotostimulated hens subjected to stimulatory photoperiod exhibited a 1.6-fold increase in VIP in the ME/INF (quiescent 59.9 +/- 6.0 vs photostimulated 95.8 +/- 7.1 pg/microgram protein). An additional 2-fold increase in ME/INF VIP concentrations was observed in laying hens (183.0 +/- 28.5 pg/microgram protein). Coincident increases in plasma PRL were also observed. In contrast, during incubation and the photorefractory stage, a dissociation between hypothalamic VIP and plasma PRL occurred. No changes were observed in VIP in incubating hens, yet a 6-fold increase in PRL was noted, compared to layers. In addition, ME/INF VIP concentrations exhibited no change during the photorefractory stage, whereas a 28-fold decrease in plasma PRL occurred. VIP concentrations in the ME/INF of laying hens were unaffected by ovariectomy, whereas exposure to short photoperiod reduced VIP by 44%. The inhibitory effects of short photoperiod could not be reversed by administration of exogenous steroids, while steroid treatment reduced VIP concentrations by 45% in the ovariectomized hens. These results provide additional correlative evidence for a modulatory role of VIP in PRL secretion and suggest that the expression of this neuropeptide in the INF may serve as a neural link between photoperiodic mechanisms and PRL release during the avian reproductive cycle.

Gonadotrophin‐Inhibitory Hormone Receptor Expression in the Chicken Pituitary Gland: Potential Influence of Sexual Maturation and Ovarian Steroids

Gonadotrophin‐inhibitory hormone (GnIH), a hypothalamic RFamide, has been found to inhibit gonadotrophin secretion from the anterior pituitary gland originally in birds and, subsequently, in mammalian species. The gene encoding a transmembrane receptor for GnIH (GnIHR) was recently identified in the brain, pituitary gland and gonads of song bird, chicken and Japanese quail. The objectives of the present study are to characterise the expression of GnIHR mRNA and protein in the chicken pituitary gland, and to determine whether sexual maturation and gonadal steroids influence pituitary GnIHR mRNA abundance. GnIHR mRNA quantity was found to be significantly higher in diencephalon compared to either anterior pituitary gland or ovaries. GnIHR mRNA quantity was significantly higher in the pituitaries of sexually immature chickens relative to sexually mature chickens. Oestradiol or a combination of oestradiol and progesterone treatment caused a significant decrease in pituitary GnIHR mRNA quantity relative to vehicle controls. GnIHR‐immunoreactive (ir) cells were identified in the chicken pituitary gland cephalic and caudal lobes. Furthermore, GnIHR‐ir cells were found to be colocalised with luteinising hormone (LH)β mRNA‐, or follicle‐stimulating hormone (FSH)β mRNA‐containing cells. GnIH treatment significantly decreased LH release from anterior pituitary gland slices collected from sexually immature, but not from sexually mature chickens. Taken together, GnIHR gene expression is possibly down regulated in response to a surge in circulating oestradiol and progesterone levels as the chicken undergoes sexual maturation to allow gonadotrophin secretion. Furthermore, GnIHR protein expressed in FSHβ or LHβ mRNA‐containing cells is likely to mediate the inhibitory effect of GnIH on LH and FSH secretion.

Vasoactive intestinal peptide stimulates prolactin mRNA expression in turkey pituitary cells: effects of dopaminergic drugs.

Abstract It is well documented that vasoactive intestinal peptide (VIP) is a prolactin (PRL)-releasing factor and that dopamine (DA) is an inhibitory neurotransmitter in avian species. However, the roles of VIP and DA in the regulation of PRL gene expression are unclear. In this study, primary anterior pituitary cells cultured from laying turkeys were utilized to investigate the influence of VIP and dopaminergic D1 and D2 receptors on PRL secretion, PRL mRNA, and PRL synthesis. Incubation of pituitary cells with VIP increased PRL secretion up to 3.5-fold within 3 hr. Prolactin mRNA was undetectable during the first 2 hr of pituitary cell treatment; thereafter, the PRL mRNA content response to VIP increased within 24-48 h (P < 0.05). Total PRL content (media + cellular) increased over time in the presence of VIP. The response of cells incubated in the presence of a dopaminergic D1 receptor agonist (SKF38393) was variable and inconclusive. However, cells incubated with a dopaminergic D2 receptor agonist (quin-pirole) inhibited VIP-induced PRL secretion (P < 0.05) and PRL mRNA levels (P < 0.05) in a dose-related fashion without effect on the basal levels of PRL release and PRL mRNA. These observations suggest that VIP, in addition to acting as a PRL-releasing peptide, also plays a role in the regulation of PRL gene expression. Moreover, the results of this study also indicate that a drug that can selectively stimulate dopamine D2 receptors can also regulate PRL secretion and PRL mRNA in turkey pituitary cells in culture. [P.S.E.B.M. 1996, Vol 212]

Immunocytochemistry and immunoblotting of avian prolactins using polyclonal and monoclonal antibodies toward a synthetic fragment of chicken prolactin

A major obstacle in the production of specific antibodies toward chicken prolactin (PRL) has been overcome by mimicking a putative epitope of the molecule using the synthetic decapeptide Lys-chPRL 59-67. This peptide represents the highest hydrophilicity peak of the amino acid sequence of chPRL that was recently derived from the nucleotide sequence. Polyclonal mouse antisera against the fragment specifically recognized the lactotropes in the cephalic lobe of the chicken pars distalis as illustrated by immunocytochemical double staining experiments. Monoclonal antibody production yielded antibodies that specifically labeled purified turkey PRL upon SDS-PAGE separation and immunoblotting. Turkey and chicken PRL showed a very similar polymorphism with respect to their apparent molecular weights, including the occurrence of a glycosylated variant of chicken PRL. The monoclonal antibodies were finally used to demonstrate the presence of PRL-like immunoreactivity both in the pituitary gland and in the brain of the quail. In the brain, immunoreactive neurons were in the nucleus accumbens and in the lateral parts of the ventro-medial hypothalamus, partly similar to those described in the rat.

Identification of growth-hormone- and prolactin-containing neurons within the avian brain

Abstract. Prolactin (PRL)- and growth-hormone (GH)-containing perikarya and fibers independent of the anterior pituitary gland have been reported to exist in the central nervous system of several mammalian species. The specific distributions of PRL- or GH-like neurons in the avian forebrain and midbrain, however, have not been reported. The objective of the study was to identify GH- and PRL-containing neurons in the hypothalamus and a few extrahypothalamic areas of two avian species. Brain and peripheral blood samples were collected from laying and broody turkey hens and ring doves. Broody turkey hens and doves had significantly higher plasma PRL concentrations compared with laying hens. Coronal brain sections were prepared and immunostained using anti-turkey GH and anti-chicken synthetic PRL antibodies. In turkey hens, the most dense GH-immunoreactive (ir) perikarya and fibers were found in hippocampus (Hp), periventricular hypothalamic nucleus, paraventricular nucleus, inferior hypothalamic nucleus, infundibular hypothalamic nucleus, medial and lateral septal area, and external zone of the median eminence (ME). In the ring dove, a similar pattern of distribution of GH-ir neurons was noticed at the brain sites listed above except that GH-ir fibers and granules were found only in the internal zone of ME and not in the external zone. In both turkeys and doves, the most immunoreactive PRL-ir perikarya and fibers were found in the medial and lateral septal area, Hp (turkey only), and bed nucleus of the stria terminalis pars magnocellularis. There were no apparent differences in the staining pattern of GH- or PRL-ir neurons between the laying and broody states in either species. However, the presence of GH-ir- and PRL-ir perikarya and fibers in several hypothalamic nuclei indicates that GH and PRL may influence parental behavior, food intake, autonomic nervous system function, and/or reproduction.

FSH- and LH-cells originate as separate cell populations and at different embryonic stages in the chicken embryo.

The histological distribution of gonadotrophs containing either LH or FSH, but not both gonadotropins, has been demonstrated before in the juvenile and adult chicken throughout the caudal and cephalic anterior pituitary lobes. In the present investigation, the distribution of FSH- and/or LH-containing gonadotrophs was further investigated in the chicken embryo by use of the same homologous antibodies as used in our earlier study. Fluorescent dual-labeling immunohistochemistry revealed that during embryogenesis LH and FSH reside exclusively in separate gonadotrophs, as has been described before in the post hatch bird. LH-immunoreactive cells were observed for the first time at day 9 of embryogenesis. This is as much as 4 days earlier than the FSH-immunoreactive cells, which appeared at day 13 of embryogenesis. Our results confirm that FSH- and LH-containing gonadotrophs are distributed throughout both lobes of the anterior pituitary. No conspicuous differences were observed between the sexes in any of the aspects investigated. The described situation is unique in that it seems to imply the existence of separate cell lineages for FSH- and LH-producing cells, as opposed to the single gonadotrope lineage described in all other species studied so far, with the exception of bovine. Our data indeed raise the question as to which signaling and/or transcription factors may cause the unique dichotomy observed in the chicken gonadotrophs.

Chronic administration of growth hormone (GH) to adult chickens exerts marked effects on circulating concentrations of insulin-like growth factor-I (IGF-I), IGF binding proteins, hepatic GH regulated gene I, and hepatic GH receptor mRNA.

In young birds, growth hormone (GH) administration has been found to have only a small or even no effect on circulating concentrations of insulin-like growth factor-I (IGF-I). This is in obvious contrast to the situation in mammals. The present study examines the effect of continuous administration of GH in adult male chickens. Plasma concentrations of IGF-I were markedly elevated (2.5–3.0-fold,p<0.001) in GH-treated chickens. There were also some transient increases in the circulating levels of IGF binding proteins. Adult chickens showed other manifestations of increased responsiveness to GH, including elevated hepatic expression of GH-regulated gene-I (mRNA) with GH treatment (p<0.05), and a tendency (p<0.08) for decreased GH-receptor mRNA. In contrast to the changes in circulating concentrations of GH and IGF-I with GH treatment, no changes in plasma concentrations of thyroid hormones, reproductive hormones, glucose, or nonesterified fatty acids were evident.

Changes in pituitary somatotrophs and lactotrophs associated with ovarian regression in the turkey hen (Meleagris gallopavo).

Hyperprolactinemia has been associated with incubation behavior and ovarian regression in turkey hens. Preliminary data show that tamoxifen, a partial estradiol receptor antagonist, may effect ovarian regression. The objectives of the study were to induce ovarian regression in egg-laying turkey hens by administration of tamoxifen, to determine whether incubation behavior would be effected by tamoxifen treatment and to examine the distribution of lactotrophs and somatotrophs and their immunocytochemical changes in the adenohypophysis due to a change in reproductive state. Two commercial strains of turkey hens were administered tamoxifen (experimentals) or vehicle (controls) intramuscularly (40 mg/hen/d). Equal numbers of experimental and control hens were killed for sample collection after 5, 9 and 14 days (n = 4 per strain) of treatment. Blood samples were collected for hormone assay and pituitaries prepared for immunocytochemistry. Tamoxifen treatment for 9 and 14 days induced ovarian regression but not incubation behavior. Plasma luteinzing hormone levels were significantly increased after 5 and 9 days of tamoxifen administration, whereas prolactin and growth hormone levels were unchanged. Somatotrophs were found predominantly in the caudal portion and lactotrophs occurred in the cephalic lobe of the pituitary. Relative to controls, the prolactin immunoreactive area was significantly greater in tamoxifen-treated hens, whereas the growth hormone immunoreactive area was reduced.

Increased Proliferative Activity and Programmed Cellular Death in the Turkey Hen Pituitary Gland Following Interruption of Incubation Behavior

Abstract Incubation behavior or broodiness in turkey hens is characterized by ovarian regression, hyperprolactinemia, and persistent nesting. Nest-deprivation of incubating turkey hens results in disruption of broodiness accompanied by a precipitous decline in plasma prolactin (PRL) concentrations. The objective of the present study is to examine cellular changes in the pituitary gland associated with nest-deprivation for 0, 1, 2, 3, 4, or 7 days. Bromodeoxyuridine (BrdU) was administered prior to kill to study proliferative activity. Pituitary tissue sections were immunostained using turkey growth hormone (GH) antibody, and/or chicken PRL peptide antibody, and BrdU antibody. Plasma PRL concentrations declined significantly following nest-deprivation for 1 or more days. The midsagittal pituitary area immunoreactive (ir) to GH was significantly increased while that of PRL was significantly decreased following nest-deprivation for 2 or more days. Terminal deoxy-UTP nick end labeling and PRL-immunostaining revealed an abundance of apoptotic nuclei in both cephalic and caudal lobes of the anterior pituitary gland, suggestive of programmed cellular death of lactotrophs in the pituitary gland of hens nest-deprived for 2 or more days. Mammosomatotrophs were abundant in hens nest-deprived on Day 0 but were absent in hens nest-deprived for 1 or more days. Proliferating (BrdU-ir) cells were significantly abundant in the pituitary cephalic and caudal lobes following nest-deprivation for 1 or more days but were absent on Day 0 or in laying hens. Dual-labeling studies indicated that most of the BrdU-ir nuclei in the caudal lobe were not colocalized in somatotrophs in hens nest-deprived for 1–4 days but did colocalize with GH following 7 days of nest-deprivation. In conclusion, nest-deprivation of incubating turkey hens results in 1) a precipitous decline in plasma PRL concentration, 2) programmed cell death of lactotrophs, 3) disappearance of mammosomatotrophs, 4) increased proliferative activity of pituitary cells, and 5) recruitment of somatotrophs arising primarily from mitosis of nonsomatotrophic cells.

Plasma prolactin responses to serial bleeding in turkeys

Abstract Changes in plasma prolactin (PRL) in response to serial bleeding by venipuncture were measured in turkeys of varying age, sex and reproductive condition. Serial bleeding increased plasma PRL levels in immature, ovariectomized (OVX), laying and non-laying females, but depressed PRL levels in broody (incubating) females. Immature males showed a positive PRL response, while mature males showed no significant response to serial bleeding. The effective stressor was shown to be repeated capture and restraint for serial bleeding and not blood loss. The pattern of the PRL response in OVX hens was not significantly influenced by variations in time required for capture and restraint or by variation in the fear reaction to capture. Habituation of OVX hens to serial capture and handling on 14 consecutive days did not significantly blunt the PRL response to serial bleeding. These results reaffirm the importance of understanding the role of physiological and psychological factors influencing PRL secretion in birds as well as the need to avoid undue stress in birds used for studies of PRL secretion.