Migraine et sensibilisation centrale : Rôles de l'amygdale dans les troubles sensoriels et anxio/dépressifs dans un modèle de migraine chez le rat. / Migraine and central sensitization : Role of the amygdala in sensory disorders and anxiety/depression in a reat model of migraine

Jacquot, Florian

18 December 2014

La migraine est un désordre neurovasculaire caractérisé par des crises récurrentes de céphalée accompagnées de troubles neurologiques variables dont l'allodynie cutanée.Chez un petit nombre de patients, la migraine passe du stade épisiodique au stade chronique, ou transformation migraineuse. Des études cliniques indiquent que la prévalence de troubles psychiatriques( anxiété/dépression) est plus élevé chez les migraineux chronique que chez le migraineux épisodique. Cependant des telles études ne permettent pas de déterminer le lien de causalité. Le but de ce travail est d'étudier le rôle de la répétition des crises de migraine sur l'apparition d'un état anxio-dépressif et ses mécanismes. Cette étude a été réalisée dans un modèle de migraine chez le rat : injections répétées de soupe inflammatoire (SI) au niveau des méninges.[...]Ces résultats suggèrent que l'apparition de troubles anxio-dépressifs chez le migraineux chronique est une conséquence directe de la répétition des crises. Cette anxiété résulte, entres autres, d'une sensiblisation du MeA impliquant les canaux ASICS1a. Ainsi élucider les mécanismes impliqués dans l'apparition de troubles anxio-dépressifs doit aider à comprendre la transformation migraineuse et améliorer son traitement. / Migraine is a common episode neurovascular disorder that manifest as reccurent attacks of severe headache together with variable neurological symptômes such as cutaneous allodyna. In subgroup of patients, attack frequency increases over time leading to chronic migraine. Clinical studies indicate that patients with episodic migraine are more likely to have anxiety symptoms than patients with episodic migraine..However, in cross-sectional studies, it is not possible to disentangle causal sequence. Our aim is to assess the role oh headache repetition on anxiety/depression symptoms. We use a rat model of migraine : stimulation of meningeal nociceptors by injecting an inflammatory soup (SI)[...]Such anxiety is due, at least in part, to MeA, sensitization involving ASIC1a channels. Dissecting out the mechanisms of the appearance of anxiety/depression symptoms following repeated migraine attacks in thus helping to understand migraine transformation and in turn to improve therapy.

Migraine

Amygdale médiane

Anxiété/dépression

ASIC 1A

Migraine

Medial amygdala

Behiavor

Anxiety/depression

ASIC 1A

570

610

Actions of Selective Estrogenic Drugs Implanted Into the Medial Amygdala on Male Rat Mating Behavior

Dunigan, Anna I

04 April 2012

Estrogen stimulation of the medial amygdala (MEA) of the brain promotes male rat mating behavior. However, selective stimulation of either of the estrogen receptor subtypes found in the MEA (ERα or ERβ) does not support mating behavior. We tested the hypothesis that dual stimulation of ERα and ERβ is required to activate estrogen-dependant neural circuits in the MEA responsible for mating by local treatment of MEA with a combination of selective estrogenic agonists: propyl pyrazole triol (PPT, an ERα agonist ) and diarylpropionitrile (DPN, an ERβ agonist) administered to castrated, DHT maintained male rats. Estradiol (E2) or cholesterol (Chol) MEA implants served as positive and negative controls respectively. The animals receiving a mixture of PPT and DPN into the MEA displayed higher levels of mating behavior than the Chol treated animals but lower levels of mating behavior than the E2 treated animals.

Estradiol

Estrogen receptor

Medial amygdala

Sexual behavior

Propyl pyrazole triol (PPT)

Diarylpropionitrile (DPN)

Methyl-piperidino-pyrazole (MPP)

Mating

Sensory Representation of Social Stimuli in Aromatase Expressing Neurons in the Medial Amygdala

Gualtieri, Charles J

14 May 2021

The ability of animals to sense, interpret, and respond appropriately to social stimuli in their environment is essential for identifying and distinguishing between members of their own species. In mammals, social interactions both within and across species play a key role in determining if an animal will live to pass on its genes to the next generation or else be removed from the gene pool. The result of this selection pressure can be observed in specialized neural circuits that respond to social stimuli and orchestrate appropriate behavioral responses. This highly conserved network of brain structures is often referred to as the Social Behavior Network (SBN). The medial amygdala (MeA) is a central node in the SBN and has been shown to be involved in transforming information from olfactory sensory systems into social and defensive behavioral responses. Previous research has shown that individual neurons in the MeA of anesthetized mice respond selectively to different chemosensory social cues, a characteristic not observed in its upstream relay, the accessory olfactory bulb (AOB). However, the cause of this stimulus selectivity in the MeA is not yet understood. Here, I hypothesize that a subpopulation of neurons in the MeA that express the enzyme aromatase are involved in the sensory representation of social stimuli in awake, behaving animals. To test this hypothesis, I designed and built a novel behavioral apparatus that allows for discrete presentations of social stimuli in a highly controllable and reproducible environment. I then injected the adeno-associated virus (AAV) AAV-Syn-Flex-GCAMP6s into the MeA of Aromatase:Cre transgenic mice and implanted a fiber optic cannula slightly above the injection site. The combination of this transgenic mouse line and conditional AAV caused GCaMP6s expression to be exclusive to aromatase-expressing neurons. By coupling my novel behavioral apparatus to a fiber photometry system, I successfully recorded the moment-to-moment activity of aromatase neurons in the MeA of awake, behaving animals as they investigated various social stimuli. Aromatase neurons in the MeA of adult male mice respond strongly to conspecific social stimuli, including live adult mice, mouse pups, and mouse urine samples. Sniffing and investigative behaviors correlated strongly with increased GCaMP6s signal in aromatase neurons, reflecting increases in their neural activity. Interestingly, after repeated investigations of the same stimuli the activity of aromatase neurons gradually diminished. Presenting a novel stimulus following repeated investigations of a familiar stimulus reinstated some, but not all of the initial GCaMP6s signal. This points to the potential role that aromatase neurons may play in the habituation to social stimuli that are consistently present in their environment. Investigations of predator stimuli did not evoke significant responses from aromatase neurons, nor did investigations of non-social stimuli. These results demonstrate that aromatase expressing neurons in the MeA of awake, behaving animals encode the sensory representation of conspecific social stimuli, and their responses are highly selective to the type of stimulus presented.

Medial Amygdala

Social Behavior

Aromatase

GCaMP

Fiber Photometry

Neural Circuitry

Behavioral Neurobiology

Molecular and Cellular Neuroscience

Systems Neuroscience

Role of the ventromedial hypothalamus in control of innate defensive behaviours

Wroblewska, Natalia

January 2018

Our senses are constantly bombarded with information. How does the brain integrate such a variety of inputs to generate appropriate behaviours? Innate defensive behaviours are a good model to address this question. They are essential for animal survival and the brain circuits that control them are highly conserved across species. Moreover, the sensory inputs and behavioural outputs can be well defined and reliably reproduced in the lab. This allows us to study function of the individual components of the circuit controlling these behaviours. Ventromedial hypothalamus (VMH) is a key brain region for controlling responses to predators; it has been shown that inactivating the VMH can reduce defensive behaviours. Interestingly, activating the VMH output neurons (SF1+ cells) can produce a variety of different behaviours, from immobility to escape, depending on the intensity of activation. During my PhD I used a variety of approaches to address the question of the function of the VMH in control of defensive behaviours. At first I hypothesised that the VMH might act as a centre responsible for choosing an appropriate behavioural response according to the stimulus. I set to investigate how different activation levels of SF1+ neurons can produce such different behavioural outputs, and how this activity is modulated in vivo in response to predator stimuli. I began the project by quantifying mouse defensive behaviours in response to olfactory and auditory predator cues, as well as to the optogenetic activation of SF1+ neurons. I then questioned whether there was heterogeneity within the population of SF1+ neurons, which could explain their ability to trigger different behaviours. I performed patch clamp recordings from acute brain slices and conducted a study of the electrophysiological properties of SF1+ neurons. I next investigated how SF1+ neurons integrate excitatory inputs from the medial amygdala, a region which receives olfactory inputs from the accessory olfactory bulb. By combining optogenetics with slice electrophysiology and behavioural assessment, I described the physiology and relevance of this connection. Finally, I investigated in vivo activity in the VMH in response to predator cues by performing calcium imaging of the VMH neurons in freely moving mice. By presenting different sensory stimuli, I addressed the question of heterogeneity of the input pattern to the VMH neurons and the relationship between the VMH activity and the behavioural output. Taken all together, the results of this project have led to a hypothesis whereby the function of the VMH is to facilitate rather than directly control the choice of an appropriate behavioural response.

ERa Expression and Monogamy in Prairie Voles: An Experimental Field Study

Lambert, Connor T.

30 April 2018

No description available.

Animals

Biology

Zoology

Neurobiology

Behavioral Sciences

monogamy

estrogen receptor alpha

prairie vole

medial amygdala

social behavior

social brain

field study

RNAi vector

Central Mechanisms Regulating Pituitary-Adrenal Activity in Infant Guinea Pigs (Cavia porcellus) during Exposure to Psychological Stressors: Independent and Combined Effects of Maternal Separation and Novelty

Maken, Deborah Suzanne

11 December 2009

No description available.

Biomedical Research

Developmental Psychology

Psychobiology

Maternal Separation

c-Fos protein

CRF mRNA

ACTH

Cortisol

Psychological Stressor

Novelty

MeA

BNST

PVN

Hypothalamus

Pituitary

Adrenal

Medial Amygdala

Bed Nucleus of the Stria Terminalus

Paraventricular Nucleus

Novel Environment

HPA axis

Female-Specific Role of Ciliary Neurotrophic Factor in the Medial Amygdala in Promoting Stress Responses

Jia, Cuihong, Gill, Wesley D., Lovins, Chiharu, Brown, Russell W., Hagg, Theo

01 March 2022

Ciliary neurotrophic factor (CNTF) is produced by astrocytes which have been implicated in regulating stress responses. We found that CNTF in the medial amygdala (MeA) promotes despair or passive coping, i.e., immobility in an acute forced swim stress, in female mice, while having no effect in males. Neutralizing CNTF antibody injected into the MeA of wildtype females reduced activation of downstream STAT3 (Y705) 24 and 48 h later. In concert, the antibody reduced immobility in the swim test in females and only after MeA injection, but not when injected in the central or basolateral amygdala. Antibody injected into the male MeA did not affect immobility. These data reveal a unique role of CNTF in female MeA in promoting despair or passive coping behavior. Moreover, 4 weeks of chronic unpredictable stress (CUS) increased immobility in the swim test and reduced sucrose preference in wildtype CNTF+/+, but not CNTF-/- littermate, females. Following CUS, 10 min of restraint stress increased plasma corticosterone levels only in CNTF+/+ females. In males, the CUS effects were present in both genotypes. Further, CUS increased CNTF expression in the MeA of female, but not male, mice. CUS did not alter CNTF in the female hippocampus, hypothalamus and bed nucleus of stria terminalis. This suggests that MeA CNTF has a female-specific role in promoting CUS-induced despair or passive coping, behavioral anhedonia and neuroendocrine responses. Compared to CNTF+/+ mice, CNTF-/- mice did not show differences in CUS-induced anxiety-like behavior and sensorimotor gating function as measured by elevated T-Maze, open field and pre-pulse inhibition of the acoustic startle response. Together, this study reveals a novel CNTF-mediated female-specific mechanism in stress responses and points to opportunities for developing treatments for stress-related disorders in women.

anhedonia

BLA

basolateral amygdala

BNST

bed nucleus of stria terminalis

CNTF

ciliary neurotrophic factor

CRF

corticotropin releasing factor

CUS

chronic unpredictable stress

CeA

central amygdala

Chronic unpredictable stress

HPA

hypothalamic-pituitary-adrenal

Hyp

hypothalamus

IL-6

interleukin-6

LIF

leukemia inhibitory factor

MeA

medial amygdala

neuroendocrine response

Neutralizing antibody

PAG

periaqueductal grey

PTSD

post-traumatic stress disorder

PVN

paraventricular nucleus

passive stress-coping

stereotaxic injection

TNF

tumor necrosis factor

mPFC

medial prefrontal cortex

Biomedical Sciences