Behavioral and endocrine evaluation of the stressfulness of single-pen housing compared to group-housing and social isolation conditions.

Regulation of neuroendocrine responses is often studied in animals housed indoors in individual contiguous pens. In sheep, these housing conditions are used to control the environment, facilitate biological sampling and limit social stress. However, this type of housing also prevents exploratory behaviors and could induce stereotypies, non-compliant with welfare and possibly associated with a state of stress. In this context, we investigated the impact of housing in a single-pen, with other familiar conspecifics, on emotional state by evaluating behavioral, hormonal and neuronal measures in adult ewes. We hypothesized that emotional state would be more negative in animals housed in a single-pen for one week (Pen) than in freely moving animals (Free) but less negative than in socially isolated subjects (Isol). We tested our hypothesis in ovariectomized ewes to avoid the interaction with sexual steroid variations. Our behavioral, endocrine and neuronal (Fos activation of the corticotropin-releasing hormone neurons in the paraventricular nucleus of the hypothalamus) measures confirmed that withdrawing familiar conspecifics was sufficient to induce strong stress responses in Isol ewes, but there was no indication that Pen ewes were stressed. However, the latter showed less mastication activity than Free ewes, probably due to limited accessibility to straw. The highest plasma prolactin levels were observed in Isol and Free animals, which might result from stress and physical activity, respectively. In Free ewes, plasma dopamine was low, consistent with its inhibitory control of prolactin. However, Isol animals had both high levels of prolactin and dopamine, suggesting a dysregulated balance in socially stressed ewes. As in other species, we suggest that the regulation of prolactin by dopamine varies with stress and/or social context. Overall, this study shows that the impact of housing conditions on different neuroendocrine systems should be considered more in the future.

Morphofunctional interactions between galanin and GnRH-containing neurones in the diencephalon of the ewe. The effect of oestradiol.

In rodents, the neuropeptide galanin (Gal) is involved in controlling the release of gonadotrophin-releasing hormone (GnRH). In the female, this peptide is colocalized in a subpopulation of GnRH neurones and its expression is stimulated by oestradiol. In the ewe, the morphofunctional relationship between these two neuronal peptides is poorly understood. The morphological interaction between Gal and GnRH was studied in ewes treated with oestradiol or with colchicine and in control animals. Five ewes were treated for 6h with oestradiol implants, a treatment known to induce a preovulatory surge of GnRH, and compared with five control animals. In addition, four animals received an intracerebroventricular injection of colchicine known to increase the intracellular level of galanin immunoreactivity. The morphological relationship between the two peptides was investigated by immunofluorescence using specific antibodies on the same sections, and the results were analysed using confocal microscopy. In colchicine-treated ewes, numerous Gal-immunoreactive neurones were found in the preoptic area in the vicinity of GnRH-immunoreactive neurones, but the two peptides were never observed in the same neurone. In all animals, Gal-ir fibres were observed to be in apposition to GnRH-containing perikarya in the preoptic area and these appositions were more numerous in oestradiol-treated ewes than in control animals. In contrast with rodents, galanin was not colocalized with GnRH in the neurones of the preoptic area of ewes, but this peptide could control GnRH neuronal secretion through axosomatic interactions. However, the presence of synaptic contacts between galanin terminals and GnRH perikarya needs to be confirmed by electron microscopy. As in rodents and primates, galanin could mediate the positive feedback of oestradiol on GnRH neurones during the preovulatory surge in ewes.

Hypothalamic arcuate neuropeptide Y-neurons decrease periventricular somatostatin-neuronal activity before puberty in the female lamb: morphological arguments.

It is assumed that hypothalamic somatostatin plays a dominant role in the regulation of growth of developing lambs. On the other side, neuropeptide Y (NPY) neurons of the arcuate (ARC) nucleus are potentially involved in the control of gonadotrophins in prepubertal lambs and also of growth hormone (GH) secretion in adults. This study therefore investigated whether the transition from the prepubertal to the peripubertal period is accompanied by changes in NPY-ir and NPY mRNA content in neurons of the ARC nucleus and their putative projections to somatostatin neurons in both the ARC and periventricular (PEV) nuclei. The hypothalami of prepubertal (17-week-old) and peripubertal (32-week-old) female lambs were compared using single and double-labelling immunohistochemistry, and hybridisation in situ for NPY. Single-labelling for NPY mRNA and NPY-ir was quantified by image analysis using a light microscope and expressed as the percent area stained and/or the integral density of the reaction. Double-labelling for NPY-somatostatin relationships was analysed by confocal microscopy. Our data suggest that there are no detectable changes in NPY-ir in the PEV nucleus in the period leading up to puberty, whereas both the distributional area and intensity of NPY-labelling in the ARC are significantly higher in peripubertal compared to prepubertal sheep. In contrast, NPY mRNA levels are higher in prepubertal than in peripubertal ewes in the ARC nucleus. Confocal microscopy suggests the existence of NPY-somatostatin axo-somatic contacts in both PEV and ARC nuclei. In the PEV nucleus, the number of close appositions between NPY-ir fibres and somatostatin-ir perikarya is higher in prepubertal than in peripubertal ewes, but in the ARC no such difference was observed. In conclusion, our observations suggest that there is decreased activity of the NPY neurons of the ARC nucleus closely related to somatostatin neurons in the PEV nucleus at the onset of puberty. The withdrawal of this NPY effect may allow a higher release of somatostatin, which consequently inhibits GH secretion and stops growth. Both peptides are involved in the transmission of signals leading to stop growth at puberty.

[Hypothalamic neuropeptides and control of GnRH neurones. Neuroanatomical study in the ewe]. / Les neuropeptides hypothalamiques dans le contrôle des neurones à GnRH. Etude neuroanatomique chez la brebis.

Reproduction in mammals is directly controlled by GnRH neurons. These neurons are regulated by many external and internal factors, among which sexual steroids, in particular oestradiol, play an important part. However the mechanisms through which these steroids regulate GnRH secretion are largely unappreciated, and the neurochemical identity of central neurons liable to transmit the steroidal information to GnRH neurons is not completely clarified. Many functional neuroanatomy studies have been carried out on the ovine model, which is particularly favorable to understand the neuroendocrine mechanisms controlling reproduction. These studies have brought about the identification of some of the potential actors in this regulation. The present review reports the major results concerning two recently discovered neuropeptides, galanin and kisspeptin, which appear to be major actors in integration of signals regulating reproduction, among which steroids. These results have revealed the major interaction sites between neurons expressing these neuropeptides and GnRH neurons.

Access of dopamine to the median eminence and brain throughout local vascular pathways in sheep.

In female sheep, estradiol-dependent dopaminergic inhibition exerted by the A15 nucleus during long days (LD) results in a blockade of reproductive activity. This effect could involve the GnRH cell bodies or their terminals in the median eminence (ME). However, a vast majority of terminals of the A15 nucleus are located in neurohypophysis and only a few in the ME. Previously we demonstrated that tritiated dopamine (DA) was transferred from the venous blood of the cavernous sinus to the arterial blood supplying the brain. In the present paper, we tested the hypothesis that the transferred dopamine could reach further the brain and ME. Using isolated sheep heads harvested on short days vs. long days, we examined radioactivity in brain tissues following infusion of tritiated dopamine into the cavernous sinus. The experiment was performed in ovariectomized ewes treated with estradiol (E2) or vehicle. The mean level of radioactivity in brain was affected by season (p<0.001) and E2 (p<0.05) and was the highest during LD in E2-treated animals. In the next experiment on isolated sheep head we measured dopamine and its metabolites levels in blood and pituitary after infusion of non-radiolabeled dopamine. We observed an increase (p<0.01) in dopamine concentration in arterial blood but not in the brain. The pituitary was the only structure examined in which a tendency (p=0.06) towards increased dopamine concentration following dopamine infusion was observed. Thus, even if part of DA released from terminals within the posterior and intermediate lobes of the pituitary reaches the vessels of the ME through local vascular pathways, it is unlikely that it could affect the LHRH terminals located in ME. In addition, our results suggest that brain capillaries in the isolated head are able to maintain a functional blood brain barrier.