Chronic Stress Has Lasting Influences on Fear Extinction Cued Discrimination Early in Extinction That is Mediated by the Infralimbic Cortex

January 2020

abstract: Post-Traumatic Stress Disorder (PTSD) is characterized by intrusive memories from a traumatic event. Current therapies rarely lead to complete remission. PTSD can be modeled in rodents using chronic stress (creating vulnerable phenotype) combined with fear conditioning (modeling a traumatic experience), resulting in attenuated extinction learning and impaired recall of extinction. Studies typically investigate cognition soon after chronic stress ends; however, as days and weeks pass (“rest” period) some cognitive functions may improve compared to soon after stress. Whether a rest period between chronic stress and fear conditioning/extinction would lead to improvements is unclear. In Chapter 2, male rats were chronically stressed by restraint (6hr/d/21d), a reliable method to produce cognitive changes, or assigned to a non-stressed control group (CON). After chronic stress ended, fear conditioning occurred within a day (STR-IMM), or after three (STR-R3) or six weeks (STR-R6). During the first three extinction trials, differences emerged in fear to the non-shock context: STR-R3/R6 showed significantly less fear to the context than did STR-IMM or CON. Differences were unlikely attributable to generalization or to second-order conditioning. Therefore, a rest period following chronic stress may lead to improved fear extinction and discrimination between the conditioned stimulus and environment. In Chapter 3, the infralimbic cortex (IL) was investigated due to the IL’s importance in fear extinction. Rats were infused with chemogenetics to target IL glutamatergic neurons and then assigned to CON, STR-IMM or STR-R3. During the rest period of STR-R3 and the restraint for STR-IMM, the IL was inhibited using CNO (1mg/kg BW, i.p., daily), which ended before behavioral testing. STR-R3 with IL inhibition failed to demonstrate a tone-shock association as spontaneous recovery was not observed. CON with IL inhibition behaved somewhat like STR-IMM; freezing to the extinction context was enhanced. Consequently, inhibiting IL function during the rest period following chronic stress was particularly disruptive for learning in STR-R3, impaired freezing to a safe context for CON, and had no effect in STR-IMM. These studies show that time since the end of chronic stress (recently ended or with a delay) can interact with IL functioning to modify fear learning and response. / Dissertation/Thesis / Doctoral Dissertation Psychology 2020

Psychobiology

Chronic Stress

Fear Extinction

Infralimbic Cortex

PTSD

Identifying the Neural Circuit That Regulates Social Familiarity Induced Anxiolysis (SoFiA)

Majumdar, Sreeparna

06 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Mental health is crucially linked to social behavior. A crucial aspect of healthy social behavior involves learning to adapt emotional responses to social cues, for example learning to suppress anxiety through social familiarity, or social familiarity induced anxiolysis (SoFiA). SoFiA is well documented; however, the neural mechanisms of SoFiA are unclear. SoFiA is modeled in rats by employing a social interaction habituation (SI-hab) protocol. Using SI-hab protocol it has been determined that SoFiA represents social safety learning, which requires both anxiogenic stimulus (Anx) and social familiarity (SF) during training sessions (5-6 daily SI sessions), and SoFiA expression is dependent on infralimbic cortex (IL). Based on these findings we hypothesize that Anx and SF are processed by unique neural systems, and repeated convergence of these signals interact within IL to induce plasticity, resulting in social safety learning and anxiolysis. Following SoFiA expression, rats were either sacrificed 30 minutes {for gene expression or Neural Activity Regulated Gene (NARG) analysis} or perfused 90 minutes (for cFos immunoreactivity analysis) after SI session on social training day 5. This led to gaining insights into regions of brain involved in SoFiA response as well as the underlying molecular mechanisms. We identified amygdala, specifically the central amygdala (CeA), basomedial amygdala (BMA) and basolateral amygdala (BLA) as potential candidate regions in SoFiA response. Next, we investigated the role of IL and its efferent pathways in SoFiA expression using inhibitory DREADDs and intersectional chemogenetics to inhibit IL projection neurons and/or axons. We identified that specific projection neurons within the IL are pivotal for SoFiA expression, and that within these projections, the ones that specifically projected to the amygdala are most crucial for expression of SoFiA. / 2021-07-01

Amygdala

Anxiety

Anxiolysis

Infralimbic cortex (IL)

Neural circuitry

Social familiarity

Brain Derived Neurotrophic Factor Modulates Behavioral and Brain Responses to Social Stress

Jeffress, Elizabeth

11 May 2015

Social stress is a prevalent factor in society that can cause or exacerbate neuropsychiatric disorders including depression and posttraumatic stress disorder. According to the National Institutes of Health, 6.9% of adults in this country currently suffer from depression, and 4.1% suffer from an anxiety disorder. Unfortunately, current treatments are ineffective in reducing or alleviating symptoms in a majority of these patients. Thus, it is critical to understand how social stress changes in brain and behavior so that we might develop alternative treatments. Brain derived neurotrophic factor (BDNF), which binds to tyrosine kinase B (TrkB) receptors, plays a role in fear learning and in behavioral responses to stress, although we do not currently know whether BDNF promotes or prevents these responses. The purpose of this project was to understand how BDNF alters brain and behavior in response to social stress using a model of social stress in Syrian hamsters, termed conditioned defeat (CD). CD refers to the marked increase in submissive and defensive behavior following social defeat. Specific Aim (SA) 1 tested the hypothesis that BDNF, via TrkB receptors, promotes CD learning. Instead, we found that BDNF and a selective TrkB receptor agonist reduced CD and that a TrkB receptor antagonist enhanced CD. SA 2 tested the hypothesis that the behavioral response observed following systemic administration of TrkB-active drugs is mediated via their action in specific nodes of the neural circuit underlying CD. Unfortunately, the vehicle in which these drugs are dissolved independently activates immediate early gene expression making interpretation of these data impossible. Finally, SA 3 tested the hypothesis that BDNF alters defeat-induced neural activation at least in part by acting in the medial prefrontal cortex (mPFC). We demonstrated that BNDF microinjected into the mPFC site-specifically altered defeat-induced neural activation in the CD neural circuit supporting this hypothesis. Overall, these data suggest that BDNF acts to prevent social stress-induced changes in behavior, at least in part via the basolateral amygdala and the mPFC, and that BDNF-active drugs might be a useful avenue to pursue to discover new treatments for patients that suffer from stress-related neuropsychiatric disorders.

Tyrosine Kinase B Receptors

Basolateral Amygdala

Prelimbic Cortex

Infralimbic Cortex

Conditioned Defeat

Synaptic Plasticity

Resilience

Effect of electrical stimulation of the infralimbic and prelimbic cortices on anxiolytic-like behavior of rats during the elevated plus-maze test, with particular reference to multiunit recording of the behavior-associated neural activity / 高架式十字迷路テスト中のラット抗不安様行動に及ぼす下辺縁皮質および前辺縁皮質の電気刺激の影響とその行動に関連する神経活動のマルチユニット記録

Shimizu, Tomoko

26 November 2018

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第21422号 / 人健博第63号 / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 稲富 宏之, 教授 澤本 伸克, 教授 伊佐 正 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM

Anxiolytic-like behavior

Brain stimulation

Elevated plus-maze

Infralimbic cortex

Medial prefrontal cortex

Multiunit recording

498

Increased Neural Activity in the Prefrontal Cortex During Fear Suppression to a Safety Signal

Ka H Ng (8787026)

30 April 2020

<p>Persistent and maladaptive fear in the absence of a threat can be disruptive because it decreases an organism’s opportunity to seek life-sustaining substances. Learned safety signaling can suppress fear and encourage reward-seeking behavior, thus freeing the organism from fear induced immobilization. The infralimbic (IL) region of the prefrontal cortex is important for recalling fear extinction memories and for suppressing fear via learned safety signals. Neurons in the IL show an excitatory response to an extinguished fear cue. We thus hypothesized that neurons in the IL would encode safety by showing an excitatory response during active fear suppression to a learned safety signal. </p> <p>To assess global changes in IL activity, we monitored IL multi-unit activity to different cues while training animals in a fear-reward-safety discrimination task (Sangha, Chadick, & Janak, 2013). During the discrimination task, male rats learned that the reward cue predicted liquid sucrose, the fear cue predicted footshock and the joint presentation of both the fear and safety cues resulted in no footshock. We also counterbalanced the modality of fear and safety cues (auditory vs visual) with two separate groups of animals to control for potential sensory modality effects. Male rats showed high levels of freezing to the fear cue, and significantly reduced levels of freezing to the combined fear+safety cue. Male rats also showed high levels of port activity to the reward cue. There was no significant difference in the learning rate between the two counterbalanced conditions. </p> <p>Our multi-unit-data showed an increase in IL neuronal firing to the fear+safety cue across training sessions. This effect was consistent between the two counterbalanced conditions. We also examined single-unit activity from all animals that received light as the safety cue (n=8). This allowed us to examine the population response profile with a subset of the total animals. Although not statistically significant, our preliminary single-unit data demonstrated a decrease in the percentage of neurons that showed an inhibitory response to the fear+safety cue, but no change in the percentage of neurons that showed an excitatory response to the fear+safety cue. There was also no change in the magnitude of averaged firing rate in fear+safety excitatory or inhibitory neurons across training. Taken together, the decreased inhibition of single-unit activity in the IL may drive the increased excitation in multi-unit activity in the IL during behavioral fear suppression to a safety signal. </p>

Behavioral Neuroscience

Neuroscience

infralimbic cortex

safety learning

fear conditioning tasks

fear management

electrophysiological experiments

Multielectrode array

PTSD

animal behavior studies

Animal Model

Investigating the role of extrasynaptic GABAA receptors located in the infralimbic cortex in the binge-like alcohol intake of male C57BL/6J mice

Fritz, Brandon Michael

20 November 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Extrasynaptic GABAA receptors, often identified as those containing both α4 and δ subunits, appear to be a target for the actions of alcohol (ethanol) at relatively low concentrations, perhaps suppressing the activity of GABAergic interneurons which regulate activity in the mesolimbocortical circuit. Pharmacological studies in rodents using the δ-subunit selective agonist Gaboxadol (THIP) have found both promotional and inhibitory effects on alcohol consumption. The goal of this project was to determine the role of extrasynaptic GABAA receptors located in the infralimbic cortex (ILC) in the binge-like alcohol intake of male C57BL/6J (B6) mice. The ILC is of interest due to its demonstrated involvement in stress reactivity and alcohol exposure has been shown to interfere with extinction learning; impairments of which may be related to inflexible behavior (i.e. problematic alcohol consumption). Adult male B6 mice were bilaterally implanted with stainless steel guide cannulae aimed at the ILC and were offered limited access to 20% ethanol or 5% sucrose for 6 days. On day 7, mice were bilaterally injected with 50 or 100 ng THIP (25 or 50 ng per side respectively) or saline vehicle into the ILC. It was found that the highest dose of THIP (100 ng/mouse) increased alcohol intake relative to vehicle controls, although control animals consumed relatively little ethanol following infusion. Furthermore, THIP had no effect on sucrose consumption (p > 0.05), suggesting that the effect of THIP was selective for ethanol consumption. Together, these findings suggest that the mice that consumed ethanol may have been particularly reactive to the microinfusion process relative to animals that consumed sucrose, perhaps because ethanol consumption was not as reinforcing as sucrose consumption. In addition, the observation that THIP effectively prevented the decrease in ethanol intake on day 7 induced by the microinjection process may be related to a role for the ILC in adaptive learning processes, which in turn, promote behavioral flexibility.

Mouse

Alcohol

GABA

Binge Drinking

Infralimbic Cortex

Binge drinking -- Research

Alcohol -- Pathophysiology

Alcoholism -- Research

Prefrontal cortex

Mice as laboratory animals

Mice -- Physiology

Ethanol -- Research

Neuropsychopharmacology

GABA -- Receptors

Reinforcement (Psychology) -- Research

Stress (Psychology)

Stress (Physiology)

Pathologie du système de récompense : effets à long terme d’une exposition chronique à la nicotine et au sucrose / Pathology of the reward system : long term effects of chronic exposure to nicotine and sucrose

Reisiger, Anne-Ruth

17 October 2013

La prise volontaire de nicotine augmente l'excitabilité de la voie ILCx-BNST, entraînant une hyperactivité des neurones DA de l’ATV. Dans une première partie, l'objectif était d’étudier les neuroadaptations de la voie ILCx-BNST induites par l'auto-administration intraveineuse (AAIV) de nicotine. Les récepteurs cannabinoides CB1 contrôlent les propriétés renforçantes de la nicotine. Par conséquent, nous avons examiné le rôle des récepteurs CB1 du BNST. Nous montrons que l'acquisition de l’AAIV de nicotine est associée à une facilitation persistante de l'induction d’une potentialisation à long terme (LTP) CB1-dépendantes des synapses ILCx-BNST. La stimulation électrique du ILCx favorise également la persistance du comportement de recherche de nicotine pendant les périodes où la drogue n'est pas disponible. En outre, en utilisant la pharmacologie intra-BNST, nous montrons que la stimulation des récepteurs CB1 du BNST au cours de l’acquisition de lAAIV augmente la sensibilité aux stimuli associés à la nicotine. L’idée qu’il existe un appétit incontrôlable pour les aliments palatables, en dépit des conséquences négatives. Dans une seconde partie, notre projet a porté sur le rôle des neurones dopaminergiques (DA) de l’ATV dans la perception d’un stimulus aversif chez l’animal exposé au sucrose. Nos résultats indiquent que le sucrose augmente l'activité spontanée des neurones DA de la VTA. En outre, si un choc électrique provoque une inhibition presque complète de l'activité de VTA neurones DA chez les rats témoins, le sucrose perturbe la signalisation d'un stimulus aversif, indépendamment de l’état calorique du rat. / Learning mechanisms associated with active responding for nicotine enhanced the excitability of the ILCx-BNST pathway. The objective of this project was to better understand the involvement of the ILCx-BNST pathway in nicotine self-administration. Since the endocannabinoid system controls nicotine reinforcement and nicotine-induced synaptic modifications, we examined the role of CB1 receptors in the BNST. We showed that acquisition of nicotine IVSA was associated with a persistent facilitation of LTP induction at ILCx-BNST synapses. Behaviorally, electrical stimulation temporarily increased excessive responding to nicotine when nicotine was not available. Moreover, using intra-BNST pharmacology, we revealed that stimulation of BNST CB1 receptors enhanced sensitivity to nicotine-paired cue. In contrast, after a prolonged history of nicotine intake, it blocked drug-seeking in a reinstatement model of relapse. Drug addiction is partly due to the inability to stop using despite negative consequences. The hypothesis that palatable food induces similar uncontrolled consumption is becoming more widespread. As drug addiction is known to increases activity of VTA DA neurons, we aimed to examine whether exposure to sucrose would induce similar neuronal modifications and impair the capacity to respond to an aversive stimulus. We found that sucrose enhanced spontaneous activity of DA VTA neurons. In addition, while a footshock caused a nearly complete inhibition of activity of VTA DA neurons in control rats, sucrose disrupted signaling of an aversive stimulus. These modifications were independent from the caloric state of the rats.

Nicotine

Auto-administration intraveineuse

Cortex infralimbic

Noyau du lit de strie terminale

Récepteur CB1

Electrophysiologie in vivo

Aire tegmentale ventrale

Récompense naturelle

Stimulus aversi

Nicotine

Intravenous self-administration

Infralimbic cortex

Bed nucleus of stria terminalis

CB1 receptor

In vivo electrophysiology

Ventral tegmental area

Natural reward

Aversive stimulus