The Interaction Between Corticosterone and Circadian Timing in Regulating Emotional Behaviors in the Rat

Ionadi, Amy

23 November 2021

No description available.

Neurosciences

Biomedical Research

glucocorticoid rhythms

corticosterone

circadian disruption

limbic

limbic disruption

limbic circadian rhythms

period2

per2

period genes

bed nucleus of the stria terminalis

BNST

central nucleus of the amygdala

CeA

anhedonia

depression

sucrose preference

Signalizace personality a stresové odpovědi prostřednictvím druhotných pohlavních znaků u sociálně monogamního pěvce / Signalling of personality and stress response by secondary sexual traits in a socially monogamous passerine

Tesař, David

January 2019

Secondary sexual traits play an irreplaceable role in the reproduction of a range of animals and are used as quality and fitness sensors during pairing of individuals. Expression of these traits, ornamentes, can correlated with an individual's personal and behavioral strategies. In the case of melanin ornaments, not only the relationships with personal individuals are considered, but there is the possible connections with stress resistance and the level of stress responses too. This hypothesis is based on the pleiotropic effect of the melanocortin system, which can be used during melanogenesis but also in the production of hormones that contribute to range of stress responses. The aim of this work was to clarify the relationship between an individual's ornaments, his stress response and individuality in the barn swallows (Hirundo rustica rustica). In this work the relationship between selected ornaments and the stress reaction of the organism, stressed glucose levels measured 15 minutes after a stress stimulus, was tested. Both sexes showed a correlation between area of white tail spots and stress response. Only for males a relationship with the length of outermost tail feathers was found and a correlation with the color saturation of feathers on the throat was shown for females. The second part of...

Ecological and Physiological Effects of Proximity to Roads in Eastern Box Turtles (<i>Terrapene carolina carolina</i>)

Weigand, Nicole Marcel

01 October 2018

No description available.

Animal Sciences

Animals

Biology

Conservation

Ecology

Endocrinology

Wildlife Conservation

Wildlife Management

turtle

eastern box turtle

road

ecology

reptile

home range

radio-telemetry

habitat selection

conditional logistic regression

corticosterone

chronic stress

stress

keratin

bioassay

control-impact

endocrinology

movement

space use

management

POTENTIAL EFFECTS OF PARENTAL HEAT STRESS EXPOSURE ON HYPOTHALAMIC-PITUITARY-ADRENAL AXIS SENSITIVITY THROUGH EPIGENETIC PROCESSES.

Esther Mary Oluwagbenga (15354481)

29 April 2023

<p>  </p> <p>Heat stress affects breeder ducks raised in North America and other parts of the world, but the effects of such stress on the progenies is not known. Therefore, the objectives of this study were to investigate: 1) The objectives of this thesis were to first investigate the effect of heat stress or exposure to exogenous glucocorticoid (GC) on fertility, production performance, egg biochemistry, egg quality, and welfare of breeder Pekin ducks. 2) the effects of maternal GC on phenotypic plasticity and behavior of the F1 generation. Three studies were carried out to investigate these objectives.</p> <p>The first experiment was conducted to test the hypothesis that chronic treatment with low levels of either corticosterone or cortisol would alter heterophil to lymphocyte ratio (HLR) and immune organ morphometrics. Further, we wanted to determine if chronic treatment with either GC would elicit an increase in cortisol levels in egg albumen. To test our hypotheses, we implanted silastic capsules subcutaneously under the skin of the neck of adult ducks (n = 5/sex/dose) using propofol anesthesia. Capsules contained corticosterone, cortisol, or empty capsules as controls. Over the course of 2 weeks, blood serum, blood smears, body weights, and egg quality data were collected. After 2 weeks, ducks were euthanized using pentobarbital (FatalPlus, 396 mg/ml/kg) and body weight, weights of spleens, livers, and the number of active follicles were recorded. Blood smears were analyzed for HLR by a lab unaware of the treatment groups. Albumen GC levels were assessed using mass spectrometry. Data were analyzed using a 2- or 3-way ANOVA as appropriate and <em>post hoc </em>with Fishers protected least squares difference (PLSD). There were no treatment effects on egg quality measures or body weight. Corticosterone treatment did elicit an increase in serum corticosterone (p < 0.05), but not cortisol levels, compared to controls in both sexes. Both cortisol and corticosterone treatments increased (p < 0.05) serum levels of cortisol compared to controls. Relative spleen weights were higher (p < 0.05) in hens following corticosterone but not cortisol treatment. No other organs showed any differences among the treatment groups. Both GCs elicited an increase (p < 0.001) in HLR in hens at all time-points over the 2-week treatment period compared to controls. Cortisol, not corticosterone, elicited an increase in HLR for drakes (p < 0.05) compared to controls at day 1 after implants. Chronic treatment with cortisol, but not corticosterone, elicited an increase (p < 0.01) in egg albumen cortisol levels compared to other groups. Corticosterone was not detected in any albumen samples.</p> <p>The goal of our second experiment was to test the hypothesis that heat stress (HS) would alter welfare, egg quality, and morphometrics of breeder ducks. Furthermore, we wanted to test if HS would increase cortisol levels in egg albumen due to recent exciting findings that cortisol, not corticosterone, is isolated in egg albumen. To test our hypothesis, adult Pekin ducks were randomly assigned to two different rooms at 85% lay with 60 hens and 20 drakes per room. Baseline data including body weight, body condition scores (BCS) (such as footpad quality, eyes, nostrils, feather cleanliness, and feather quality scores), and egg production/quality were collected the week preceding heat treatment. Ducks were subjected to cyclic HS of 350C for 10h/day and to 29.50C for the remaining 14h/day for 3 weeks while the control room was maintained at 220C. Eggs were collected daily, and body weights were taken on days 0 and 21 relative to the onset of heat treatment. BCS were collected weekly. Eggs were collected weekly for quality assessment and albumen glucocorticoid (GCs) levels assessment using mass spectrometry. One week before the exposure to HS, 10 hens and 5 drakes were euthanized and the same number again after 3 weeks of HS or control exposures using pentobarbital and birds necropsied. Body weight, weights of the liver, spleen, and the number of maturing follicles were recorded. Data analyses were done by 2- or 3-way ANOVA as appropriate with a Tukey-Kramer post hoc test. BCS were analyzed using a chi-squared test. A p value ≤ 0.05 was considered significant. Circulating levels of corticosterone were significantly (p < 0.01) elevated at week 1 only in the HS hens while there was no significant difference in the circulating levels of corticosterone in drakes compared to the controls. The circulating levels of cortisol increased significantly at week 1 (p < 0.05), week 2 (p < 0.05), and week 3 (p < 0.01) in the hens and at week 2 and 3 only (p < 0.05) in the drakes compared to the controls. Feather quality scores (p < 0.01), feather cleanliness scores (p < 0.001) and footpad quality scores (p < 0.05) increased significantly in the HS group compared to controls, higher BCS indicate a decline in welfare. HS elicited a significant (p < 0.001) decrease in egg production at weeks 1 and 3 and a descriptive decrease in the number of fertile eggs upon candling at 10 days of incubation, numeric decrease hatchability and increase in the number of dead embryos in the HS group after the incubation period. Hens in the HS group showed a significantly decreased BW (p < 0.001), and number of ovarian follicles (p < 0.05) compared to controls. Shell weight decreased significantly at week 1 (p < 0.05) compared to controls. Yolk weight decreased significantly at week 3 (p < 0.01) compared to controls. HS elicited a significant increase in albumen cortisol levels at week 1 (p < 0.05) and week 3 (p < 0.05).</p> <p>The third experiment was conducted to determine if parental exposure to heat stress would impair performance, hypothalamic pituitary adrenal (HPA) axis response, welfare, or behavior of their offspring. To achieve these goals, we treated adult drakes and hens at peak lay to heat stress or control temperature for 3 weeks and incubated eggs collected from the last 3 days of the experiment. A total of 76 ducklings were placed into pens from each parental treatment group: control (CON-F1) and heat stress (HS-F1) and raised as grow-out ducks. Weekly data for body weights, body condition scores (BCS), and novel object test (NOT) were collected weekly. At 3 weeks of age, ducks (n = 6 per treatment group) were subjected to adrenocorticotropic hormone (ACTH) (ACTH/cosyntropin, 0.0625 mg/kg) challenge or vehicle as control. Blood samples were collected from the metatarsal vein into serum-separator tubes at 0, 1, 2, 3, and 4 hours relative to treatment for the determination of serum glucocorticoids. Blood smears were also produced from these same samples to determine heterophil to lymphocyte ratios (HLR). All injected birds were euthanized with pentobarbital on the second day relative to ACTH administration, spleen and bursa were removed and weighed immediately. Duck level analyses were completed using 1-, or 2 -way ANOVA as appropriate. BCS were analyzed using a chi-squared test. We observed that HS-F1 had a lower hatch weight (p < 0.05) compared to CON-F1. However, growth rates during the 5-week grow-out period were not significantly different between the two flocks. NOT (N = 4) analyses showed that the HS-F1 had a greater fear response (P< 0.001) compared to CON-F1. Similarly, an ACTH stimulation test showed that the HS-F1 ducks had significantly heightened corticosterone and HLR responses compared to CON-F1 ducks (p < 0.05). The HS-F1 showed altered baseline and ACTH-stimulated levels of cortisol compared to controls.</p> <p>In conclusion, GC elicit differential effects and although corticosterone has been stated to be the predominant GC in avian species, cortisol may provide critical information to further understand and improve welfare. HS decreased performance, fertility, and productivity of breeder ducks. In addition, HS and exogenous GC elicited a selective deposition of cortisol, not corticosterone, in the egg albumen. The maternal cortisol deposited in eggs alter the hypothalamic-pituitary adrenal (HPA) axis and behavioral responses of the F1 generation. This suggests that maternal hormones can alter the phenotypic plasticity of the offspring and can be used to produce offspring that have better adaptation to the rising temperatures as a result of climate change. Finally, the measure of cortisol in egg albumen can be used as a non-invasive marker of stress.</p>

Animal management

Animal welfare

Climate change

Heat stress

Corticosterone

Cortisol

pekin ducks

Maternal glucocorticoid

Chronic stress

Egg quality

Phenotypic plasticity

Offspring performance

HPA response

Behavior

Sex-specific differences in hippocampal development : impact on stress and epileptogenesis

Wolf, Daniele

01 1900

Les différences sexuelles ne se limitent pas uniquement aux organes de reproduction, elles sont aussi très marquées dans plusieurs pathologies humaines. De ce fait, les études impliquant un seul sexe ne pourraient jamais permettre d’élucider les mécanismes qui sous-tendent ces pathologies. De plus, l’exclusion des femelles/filles/femmes des protocoles de recherche a des impacts négatifs sur la qualité de vie des patients, plus spécifiquement celle des filles et femmes. Des études récentes ont suggéré que la testostérone et ses métabolites affectent le développement de l’hippocampe aux niveaux biochimique, morphologique et fonctionnel. En revanche, les données ne sont pas aussi extensives que celles de leurs rôles chez les adultes. Ainsi, une meilleure compréhension des mécanismes par lesquels l’hormone stéroïdienne influence le développement du cerveau facilitera l’identification des cibles thérapeutiques de plusieurs maladies neurodéveloppementales qui affectent le fonctionnement de l’hippocampe. Afin de se développer adéquatement, le cerveau mâle requiert une exposition aux hormones sexuelles mâles pendant une période de temps donnée. En revanche, le cerveau femelle possède une phase critique peu après la naissance au cours de laquelle une exposition aux hormones sexuelles mâles le masculinise en produisant des caractéristiques comparables à celles rencontrées chez des mâles biologiques. Ainsi, la capacité de manipuler les cerveaux femelles dans le but de les masculiniser représente un outil expérimental important pour investiguer les différences sexuelles. Du fait que les hormones sexuelles telles que la testostérone et l’estradiol représentent respectivement l’élément caractéristique de chacun des sexes, cette thèse a pour objectif de disséquer l’implication de la testostérone dans le développement et le fonctionnement du cerveau en étudiant en plus des rats mâles et femelles, des femelles traitées avec la testostérone ainsi que des mâles rendus insensibles à la testostérone. En premier lieu, nous avons investigué sur un système de neurotransmission spécifique, à savoir le système GABAergique, qui est important pour le contrôle des convulsions communément observées dans l’épilepsie. Ce système possède des particularités notables en fonction du sexe, particularités qui pourraient être l’une des causes de la prédisposition des mâles à l’épilepsie. En effet, notre étude révèle qu’au niveau basal, les femelles ainsi que les mâles insensibles à la testostérone montrent très tôt au cours de leur développement une localisation à la membrane du co-transporteur KCC2 qui régule la force de la neurotransmission inhibitrice. Par ailleurs, nous avons aussi détecté des niveaux élevés du neurotrophine BDNF qui est un puissant modulateur du fonctionnement des cellules GABAergiques, ceci, au cours de la première semaine postnatale. Par ailleurs, chez les adultes, nous avons trouvé que les femelles ainsi que les mâles insensibles à la testostérone montrent une augmentation de la transmission GABergique spontanée comparativement aux mâles et aux femelles qui ont été exposées à la testostérone. En somme, ces données démontrent que le fonctionnement de la circuiterie GABAergique est modulé par le niveau de testostérone périnatal, ce qui suggère d’un rôle des hormones sexuelles dans la régulation de l’excitabilité cellulaire. De plus, les différences sexuelles dans le cerveau sont largement déterminées par des facteurs extrinsèques. Parmi ces derniers, le stress du début de la vie est un facteur extrinsèque puissant qui altère l’habileté à contrôler la rétroaction négative des glucocorticoïdes sur l’axe hypothalamo-hypophyso-surrénalien (HHS). Le stress est également connu pour affecter différentiellement les rats mâles comparativement aux femelles. Nous démontrons alors que la corticostérone rend l’hippocampe vulnérable à une seconde insulte, telle que les épilepsies induites par l’hyperthermie. En effet, chez les rats traités à la corticostérone, la latence d’induction des épilepsies par hyperthermie est réduite, le temps de récupération plus long et le nombre d’évènements épileptiques plus nombreux. En outre, nous avons trouvé que tous ces effets sont plus proéminents chez les mâles que chez les femelles. Ces données confirment l’existence d’un lien entre le stress du début de la vie et la susceptibilité aux convulsions hyperthermiques chez les rats mâles et femelles. Une meilleure compréhension des conséquences des convulsions fébriles pourrait aider dans le pronostic et le traitement des patients souffrant d’épilepsie. Somme toute, cette thèse met en lumière le rôle complexe des hormones sexuelles dans la régulation des circuits GABAergiques, des réponses au stress et de l’hyperexcitabilité du cerveau en développement. Une meilleure compréhension des mécanismes pathologiques propres aux modèles animaux mâles et femelles résulterait en de meilleures interventions et thérapies aussi bien chez les hommes que les chez les femmes. / Sex differences extend far beyond reproductive health — there is a widespread prevalence of sex differences in many human diseases and conditions. Therefore, studies limited to a single-sex cannot fully give a comprehensive picture of the underlying disease mechanisms, and the neglect of females/girls/women in biological research negatively impacts patients' quality of life, especially women. Recent data suggest that testosterone and its metabolites affect the hippocampus during development at the biochemical, morphological, and functional levels, although the data are not nearly as extensive as what is known in adults. Therefore, a better understanding of these effects will elucidate steroid hormone-dependent mechanisms of brain development and, possibly, help identifying ways to mitigate the burden of the many neurodevelopmental disorders that involve hippocampal function. The male brain is unique in that it must be exposed to male sex hormones for a fixed period of time, which is so-called critical period. This is deemed a critical period because if androgens levels do not rise at this time in males, the brain will fail to be masculinized. The female brain, on the other hand, has a sensitive period shortly after birth, during which exposure to male sex hormones may masculinize the brain and produce features comparable to those seen in biological males. This capacity to manipulate females toward more masculinized brains represent an important experimental tool to investigate sex differences. Because sexual hormones, such as testosterone and estradiol, are a distinct point of divergence between sexes, my thesis proposes to study the implication of testosterone by using, in addition to male and female animals, females treated with testosterone as well as testosterone-insensitive male rats. First, we investigated a specific neurotransmitter system, the GABAergic system, which contributes to the control of seizures commonly observed in epilepsies. This system shows robust differences between males and females, which may be involved with the predisposition to epilepsy observed in males. Our study revealed that at baseline conditions female and testosterone-insensitive male rats show an earlier localization at the membrane of the chloride co-transporter KCC2, which regulates the strengths of inhibitory neurotransmission, and higher levels of the neurotrophin BDNF, which is a powerful modulator of GABAergic cell function, during the first postnatal week. In addition, we found that female and testosterone-insensitive male rats show enhanced spontaneous GABA synaptic transmission when compared to males and testosterone-exposed females in adults. Overall, these data show that perinatal testosterone levels modulate GABAergic circuit function, suggesting a role of sex hormones in regulating cell excitability. Second, sex differences in the brain are largely determined by extrinsic factors. Early-life stress is one such powerful extrinsic factor that impairs the ability to control glucocorticoid negative feedback on the HPA axis. Stress is also known to differentially affect male and female rats. Here, we show that corticosterone alone renders the hippocampus vulnerable to a second insult, namely hyperthermia-induced seizures, in fact in corticosterone-treated rats the latency to hyperthermia-induced seizures was shorter, the recovery time longer, and a larger number of hyperthermia-induced seizures. Further, these effects were a lot more prominent in males than in females. These findings support a link between early-life stress and hyperthermic seizure susceptibility in both male and female rats. A better understanding of the consequences of febrile seizures could help improve the prognosis and treatment of patients with epilepsy. Altogether, these findings shed light on the complex roles of sex hormones in regulating GABAergic circuits, stress responses and circuit hyper-excitability in the developing brain. A better understanding of disease-mechanisms underlying male and female animal models could lead to better interventions and therapeutics in both men and women.

Sex differences

Testosterone

GABAergic circuits

Hippocampus

KCC2

BDNF

Corticosterone

Chronic stress

Febrile seizures

HPA

Différences sexuelles

Testostérone

Circuits GABAergiques

Hippocampe

Corticostérone

Stress chronique

Convulsions fébriles

HHS

Corticosterone Administration up-Regulated Expression of Norepinephrine Transporter and Dopamine Β-Hydroxylase in Rat Locus Coeruleus and Its Terminal Regions

Fan, Yan, Chen, Ping Ping, Li, Ying, Cui, Kui, Noel, Daniel M., Cummins, Elizabeth D., Peterson, Daniel J., Brown, Russell W., Zhu, Meng-Yang

01 February 2014

Stress has been reported to activate the locus coeruleus (LC)-noradrenergic system. In this study, corticosterone (CORT) was orally administrated to rats for 21 days to mimic stress status. In situ hybridization measurements showed that CORT ingestion significantly increased mRNA levels of norepinephrine transporter (NET) and dopamine β-hydroxylase (DBH) in the LC region. Immunofluorescence staining and western blotting revealed that CORT treatment also increased protein levels of NET and DBH in the LC, as well as NET protein levels in the hippocampus, the frontal cortex and the amygdala. However, CORT-induced increase in DBH protein levels only appeared in the hippocampus and the amygdala. Elevated NET and DBH expression in most of these areas (except for NET protein levels in the LC) was abolished by simultaneous treatment with combination of corticosteroid receptor antagonist mifepristone and spironolactone (s.c. for 21 days). Also, treatment with mifepristone alone prevented CORT-induced increases of NET expression and DBH protein levels in the LC. In addition, behavioral tasks showed that CORT ingestion facilitated escape in avoidance trials using an elevated T-maze, but interestingly, there was no significant effect on the escape trial. Corticosteroid receptor antagonists failed to counteract this response in CORT-treated rats. In the open-field task, CORT treatment resulted in less activity in a defined central zone compared to controls and corticosteroid receptor antagonist treatment alleviated this increase. In conclusion, this study demonstrates that chronic exposure to CORT results in a phenotype that mimics stress-induced alteration of noradrenergic phenotypes, but the effects on behavior are task dependent. As the sucrose consumption test strongly suggests CORT ingestion-induced depression-like behavior, further elucidation of underlying mechanisms may improve our understanding of the correlation between stress and the development of depression.

animals

brain chemistry

corticosterone

dopamine beta-hydroxylase

exploratory behavior

fluorescent antibody technique

in situ hybridization

locus coeruleus

male

nerve tissue proteins

rats

taste

up-Regulation

animal behavior

anxiety

dopamine β-hydroxylase

norepinephrine transporter

rat brain

Biomedical Sciences

Neurosciences