Beyond the Activity-Based Anorexia Model: Reinforcing Values of Exercise and Feeding Examined in Stressed Adolescent Male and Female Mice

Anorexia nervosa (AN), mostly observed in female adolescents, is the most fatal mental illness. Its core is a motivational imbalance between exercise and feeding in favor of the former. The most privileged animal model of AN is the “activity-based anorexia” (ABA) model wherein partly starved rodents housed with running wheels exercise at the expense of feeding. However, the ABA model bears face and construct validity limits, including its inability to specifically assess running motivation and feeding motivation. As infant/adolescent trauma is a precipitating factor in AN, this study first analyzed post-weaning isolation rearing (PWIR) impacts on body weights and wheel-running performances in female mice exposed to an ABA protocol. Next, we studied through operant conditioning protocols i) whether food restriction affects in a sex-dependent manner running motivation before ii) investigating how PWIR and sex affect running and feeding drives under ad libitum fed conditions and food restriction. Besides amplifying ABA-elicited body weight reductions, PWIR stimulated wheel-running activities in anticipation of feeding in female mice, suggesting increased running motivation. To confirm this hypothesis, we used a cued-reward motivated instrumental task wherein wheel-running was conditioned by prior nose poke responses. It was first observed that food restriction increased running motivation in male, but not female, mice. When fed grouped and PWIR mice were tested for their running and palatable feeding drives, all mice, excepted PWIR males, displayed increased nose poke responses for running over feeding. This was true when rewards were proposed alone or within a concurrent test. The increased preference for running over feeding in fed females did not extend to running performances (time, distance) during each rewarded sequence, confirming that motivation for, and performance during, running are independent entities. With food restriction, mice displayed a sex-independent increase in their preference for feeding over running in both group-housed and PWIR conditions. This study shows that the ABA model does not specifically capture running and feeding drives, i.e. components known to be affected in AN

Intracellular dynamic of CA3 pyramidal cells of the hippocampus during awake states

Les états de veille sont composés d’états cérébraux distincts, corrélés avec différents comportements et caractérisés par des oscillations spécifiques observables dans le potentiel de champ local (Local Field Potential, LFP). Bien que les différents états cérébraux et leur signature dans le LFP aient été caractérisés, les mécanismes cellulaires sous-jacents restent à ce jour peu connus. Des changements des propriétés de neurones uniques seraient corrélés avec, et pourraient participer à la génération de ces changements d’états cérébraux. L’activité coordonnée et synchronisée de neurones facilite certains processus cognitifs tels que la mémoire. L’hippocampe joue un rôle essentiel dans les mémoires spatiale et épisodique, et dans l’hippocampe, CA3 est important pour la formation d’associations facilitant l’encodage rapide de la mémoire. De plus, les informations provenant du cortex entorhinal, du gyrus denté, et de CA3 même sont comparées et intégrées dans CA3 avant d’être transmises à CA1. Lors de périodes de repos, le LFP hippocampique présente une activité large et irrégulière (Large Irregular Activity, LIA), ponctuée par des oscillations plus rapides, les sharp-wave ripples, jouant un rôle dans la consolidation de la mémoire. Lors de périodes exploratoires, le LFP hippocampique oscille aux fréquences theta (6-12 Hz) et gamma (30-100 Hz). Les cellules pyramidales (CP) de CA3 jouent un rôle important dans chacun de ces états ; elles sont nécessaires pour les sharp wave lors de périodes de repos, et les oscillations gamma lors de comportements exploratoires. Dans le but d’étudier les modulations intracellulaires des CP de CA3, nous avons réalisé des enregistrements de patch-clamp en configuration cellule entière chez l’animal éveillé. Nous avons associé ces enregistrements avec des mesures du diamètre pupillaire et de la vitesse de locomotion de l’animal, ainsi qu’avec l’enregistrement de l’activité oscillatoire du LFP dans l’hippocampe. Nos résultats montrent que certaines CP de CA3 sont sensibles à la modulation intracellulaire lors de différents rythmes hippocampiques, et ont tendance à diminuer leur potentiel de membrane moyen, leur excitabilité, leur variance et leur décharge de potentiel d’action lors des oscillations theta par rapport aux périodes de LIA. De futures études permettront de déterminer si ces changements sont dus à des changements d’entrées synaptiques et/ou de neuromodulateurs. Ces modulations pourraient jouer un rôle dans l’émergence des rythmes oscillatoires du LFP, et permettre à CA3 de réaliser différentes fonctions mnésiques à différents moments.Wakefulness is comprised of distinct brain states, correlated with different behaviors and characterized by specific oscillatory patterns in the local field potential (LFP). While much work has characterized different brain states and their LFP signatures, the underlying cellular mechanisms are less known. Changes in single cell properties are thought to correlate with and possibly result in these changes in brain state. Synchronized and coordinated activity among distributed neurons supports cognitive processes such as memory. The hippocampus is essential for spatial and episodic memory, and within the hippocampus, area CA3 is important for rapid encoding of one-trial memory. Additionally, CA3 is the site where information from the entorhinal cortex, dentate gyrus, and CA3 itself is compared and integrated before output to CA1. During quiet wakefulness, the hippocampal LFP displays large irregular activity (LIA) punctuated by sharp-wave ripples, which play a role in memory consolidation. During exploratory behaviors, hippocampal LFP oscillates at both theta and gamma frequencies. CA3 pyramidal cells (PCs) play an important role in each of these brain states; they are necessary for both sharp waves during quiet wakefulness and for gamma oscillations during exploratory behavior. We explored the changes that occur in the intracellular dynamics of CA3 PCs during changes in brain state, by using whole-cell patch-clamp recordings from CA3 PCs in awake head-fixed mice. We combined those recordings with measurements of pupil diameter, treadmill running speed and LFP recordings of oscillatory activity. Our findings show that some CA3 PCs are prone to intracellular modulation during brain rhythms, and tend to decrease their average membrane potential, excitability, variance and output firing during theta as compared to LIA. Future studies will demonstrate whether these effects are due to changes in synaptic and/or neuromodulatory inputs. This modulation at the single-cell level in CA3 could play a role in the emergence of oscillations, and underlie the ability of CA3 to perform different memory functions during different brain states

Dynamique intracellulaire des cellules pyramidales de CA3 dans l'hippocampe pendant les états de veille

Wakefulness is comprised of distinct brain states, correlated with different behaviors and characterized by specific oscillatory patterns in the local field potential (LFP). While much work has characterized different brain states and their LFP signatures, the underlying cellular mechanisms are less known. Changes in single cell properties are thought to correlate with and possibly result in these changes in brain state. Synchronized and coordinated activity among distributed neurons supports cognitive processes such as memory. The hippocampus is essential for spatial and episodic memory, and within the hippocampus, area CA3 is important for rapid encoding of one-trial memory. Additionally, CA3 is the site where information from the entorhinal cortex, dentate gyrus, and CA3 itself is compared and integrated before output to CA1. During quiet wakefulness, the hippocampal LFP displays large irregular activity (LIA) punctuated by sharp-wave ripples, which play a role in memory consolidation. During exploratory behaviors, hippocampal LFP oscillates at both theta and gamma frequencies. CA3 pyramidal cells (PCs) play an important role in each of these brain states; they are necessary for both sharp waves during quiet wakefulness and for gamma oscillations during exploratory behavior. We explored the changes that occur in the intracellular dynamics of CA3 PCs during changes in brain state, by using whole-cell patch-clamp recordings from CA3 PCs in awake head-fixed mice. We combined those recordings with measurements of pupil diameter, treadmill running speed and LFP recordings of oscillatory activity. Our findings show that some CA3 PCs are prone to intracellular modulation during brain rhythms, and tend to decrease their average membrane potential, excitability, variance and output firing during theta as compared to LIA. Future studies will demonstrate whether these effects are due to changes in synaptic and/or neuromodulatory inputs. This modulation at the single-cell level in CA3 could play a role in the emergence of oscillations, and underlie the ability of CA3 to perform different memory functions during different brain states.Les états de veille sont composés d’états cérébraux distincts, corrélés avec différents comportements et caractérisés par des oscillations spécifiques observables dans le potentiel de champ local (Local Field Potential, LFP). Bien que les différents états cérébraux et leur signature dans le LFP aient été caractérisés, les mécanismes cellulaires sous-jacents restent à ce jour peu connus. Des changements des propriétés de neurones uniques seraient corrélés avec, et pourraient participer à la génération de ces changements d’états cérébraux. L’activité coordonnée et synchronisée de neurones facilite certains processus cognitifs tels que la mémoire. L’hippocampe joue un rôle essentiel dans les mémoires spatiale et épisodique, et dans l’hippocampe, CA3 est important pour la formation d’associations facilitant l’encodage rapide de la mémoire. De plus, les informations provenant du cortex entorhinal, du gyrus denté, et de CA3 même sont comparées et intégrées dans CA3 avant d’être transmises à CA1. Lors de périodes de repos, le LFP hippocampique présente une activité large et irrégulière (Large Irregular Activity, LIA), ponctuée par des oscillations plus rapides, les sharp-wave ripples, jouant un rôle dans la consolidation de la mémoire. Lors de périodes exploratoires, le LFP hippocampique oscille aux fréquences theta (6-12 Hz) et gamma (30-100 Hz). Les cellules pyramidales (CP) de CA3 jouent un rôle important dans chacun de ces états ; elles sont nécessaires pour les sharp wave lors de périodes de repos, et les oscillations gamma lors de comportements exploratoires. Dans le but d’étudier les modulations intracellulaires des CP de CA3, nous avons réalisé des enregistrements de patch-clamp en configuration cellule entière chez l’animal éveillé. Nous avons associé ces enregistrements avec des mesures du diamètre pupillaire et de la vitesse de locomotion de l’animal, ainsi qu’avec l’enregistrement de l’activité oscillatoire du LFP dans l’hippocampe. Nos résultats montrent que certaines CP de CA3 sont sensibles à la modulation intracellulaire lors de différents rythmes hippocampiques, et ont tendance à diminuer leur potentiel de membrane moyen, leur excitabilité, leur variance et leur décharge de potentiel d’action lors des oscillations theta par rapport aux périodes de LIA. De futures études permettront de déterminer si ces changements sont dus à des changements d’entrées synaptiques et/ou de neuromodulateurs. Ces modulations pourraient jouer un rôle dans l’émergence des rythmes oscillatoires du LFP, et permettre à CA3 de réaliser différentes fonctions mnésiques à différents moments

Neural Circuits for Emotion

Emotions are fundamental to our experience and behavior, affecting and motivating all aspects of our lives. Scientists of various disciplines have been fascinated by emotions for centuries, yet even today vigorous debates abound about how to define emotions and how to best study their neural underpinnings. Defining emotions from an evolutionary perspective and acknowledging their important functional roles in supporting survival allows the study of emotion states in diverse species. This approach enables taking advantage of modern tools in behavioral, systems, and circuit neurosciences, allowing the precise dissection of neural mechanisms and behavior underlying emotion processes in model organisms. Here we review findings about the neural circuit mechanisms underlying emotion processing across species and try to identify points of convergence as well as important next steps in the pursuit of understanding how emotions emerge from neural activity

Early synaptic deficits in the APP/PS1 mouse model of Alzheimer's disease involve neuronal adenosine A2A receptors

Synaptic plasticity in the autoassociative network of recurrent connections among hippocampal CA3 pyramidal cells is thought to enable the storage of episodic memory. Impaired episodic memory is an early manifestation of cognitive deficits in Alzheimer's disease (AD). In the APP/PS1 mouse model of AD amyloidosis, we show that associative long-term synaptic potentiation (LTP) is abolished in CA3 pyramidal cells at an early stage. This is caused by activation of upregulated neuronal adenosine A2A receptors (A2AR) rather than by dysregulation of NMDAR signalling or altered dendritic spine morphology. Neutralization of A2AR by acute pharmacological inhibition, or downregulation driven by shRNA interference in a single postsynaptic neuron restore associative CA3 LTP. Accordingly, treatment with A2AR antagonists reverts one-trial memory deficits. These results provide mechanistic support to encourage testing the therapeutic efficacy of A2AR antagonists in early AD patients