Role of the gut-brain axis in early stress-induced emotional vulnerability

Les maladies psychiatriques présentent de fortes comorbidités avec des désordres gastrointestinaux, ce qui suggère l’existence de bases physiopathologiques communes. Une littérature abondante démontre que l’adversité précoce (infection, stress) augmente la vulnérabilité aux désordres psychiatriques à l’âge adulte. Chez le rongeur, le modèle de séparation maternelle induit chez la descendance adulte des comportements hyperanxieux associés à une hypersensibilité au stress, ainsi que des dysfonctionnements de la sphère gastrointestinale. De plus, des études récentes rapportent une hyperperméabilité de la barrière intestinale chez les ratons soumis au stress de séparation, un effet conduisant potentiellement à une dysbiose et une perturbation de la communication intestin-cerveau. Le but de ma thèse était donc d’étudier le rôle de l’axe intestin-cerveau dans la mise en place des effets à long terme du stress précoce. Nos travaux récents ont montré que certains effets à long-terme de la séparation maternelle peuvent être atténués par l’exposition des mères à un régime hyperlipidique. Dans un premier temps, nous avons testé les effets du régime hyperlipidique maternel sur le cerveau et l’intestin de ratons soumis à la séparation maternelle. Nos résultats montrent que le régime maternel hyperlipidique protège de l’augmentation de la permeabilité intestinale induite par le stress. Nous avons ensuite testé le rôle causal de la perméabilité intestinale sur les comportements émotionnels à travers une approche pharmacologique et une approche génétique. Nous rapportons 1) que la restauration de la fonction barrière de l’intestin atténue certains effets de la séparation maternelle et 2) qu’une hyperperméabilité intestinale chez des souris transgéniques non soumises à un stress produit des effets similaires à ceux de la séparation maternelle. Enfin, nous avons examiné les effets d’une adversité précoce multifactorielle sur le cerveau et l’intestin (perméabilité et microbiote) chez la descendance adulte mâle et femelle dans un modèle combinant infection prénatale et séparation maternelle. Nos résultats mettent en évidence un effet sexe très marqué sur les phénotypes comportements et intestinaux. D’autres études sont nécessaires pour identifier les mécanismes sous-tendant les effets de la perméabilité et la dysbiose intestinale sur la vulnérabilité émotionnelle associée au stress précoce.Early-life adversity is a main risk factor for psychiatric disorders at adulthood; however the mechanisms underlying the programming effect of stress during development are still unknown. In rodents, chronic maternal separation has long lasting effects in adult offspring, including hyper-anxiety and hyper-responsiveness to a novel stress, along with gastrointestinal dysfunctions. Moreover, recent studies report gut barrier hyper-permeability in rat pups submitted to maternal separation, an effect that could potentially lead to dysbiosis and altered gut-brain communication. Therefore, the aim of my PhD was to unravel the role of the gut-brain axis in the neurobehavioral effects of early-life stress. We recently reported that some neural, behavioral and endocrine alterations associated with maternal separation in rats could be prevented by maternal exposure to a high-fat diet. We first addressed the effects of maternal high-fat diet on brain and gut during development in the maternal separation model. We show that maternal high-fat diet prevents the stress-induced decrease in spine density and altered dendritic morphology in the medial prefrontal cortex. Moreover, maternal high-fat diet also attenuates the exacerbated intestinal permeability associated with maternal separation. To explore a potential causal impact of gut leakiness on brain functions, we then examined the impact of pharmacological and genetic manipulations of intestinal permeability on brain and behavior. We report 1) that restoration of gut barrier function attenuates some of the behavioral alterations associated with maternal separation and 2) that chronic gut leakiness in naive adult transgenic mice recapitulates the effects of maternal separation. Finally, we examined the effects of multifactorial early-life adversity on behavior, gut function and microbiota composition in males and females using a combination of prenatal inflammation and maternal separation in mice. At adulthood, offspring exposed to early adversity displayed sex-specific behavioral (social behavior deficits in males and increased anxiety in females) and intestinal phenotypes. In conclusion, our work demonstrates an impact of gut dysfunctions, in particular gut leakiness, on the emergence of emotional alterations. Further studies are needed to unravel the role of the gut dysbiosis in the expression of the behavioral phenotypes associated with early-life adversity

Implication de l’axe intestin-cerveau dans la vulnérabilité émotionnelle associée au stress précoce

Early-life adversity is a main risk factor for psychiatric disorders at adulthood; however the mechanisms underlying the programming effect of stress during development are still unknown. In rodents, chronic maternal separation has long lasting effects in adult offspring, including hyper-anxiety and hyper-responsiveness to a novel stress, along with gastrointestinal dysfunctions. Moreover, recent studies report gut barrier hyper-permeability in rat pups submitted to maternal separation, an effect that could potentially lead to dysbiosis and altered gut-brain communication. Therefore, the aim of my PhD was to unravel the role of the gut-brain axis in the neurobehavioral effects of early-life stress. We recently reported that some neural, behavioral and endocrine alterations associated with maternal separation in rats could be prevented by maternal exposure to a high-fat diet. We first addressed the effects of maternal high-fat diet on brain and gut during development in the maternal separation model. We show that maternal high-fat diet prevents the stress-induced decrease in spine density and altered dendritic morphology in the medial prefrontal cortex. Moreover, maternal high-fat diet also attenuates the exacerbated intestinal permeability associated with maternal separation. To explore a potential causal impact of gut leakiness on brain functions, we then examined the impact of pharmacological and genetic manipulations of intestinal permeability on brain and behavior. We report 1) that restoration of gut barrier function attenuates some of the behavioral alterations associated with maternal separation and 2) that chronic gut leakiness in naive adult transgenic mice recapitulates the effects of maternal separation. Finally, we examined the effects of multifactorial early-life adversity on behavior, gut function and microbiota composition in males and females using a combination of prenatal inflammation and maternal separation in mice. At adulthood, offspring exposed to early adversity displayed sex-specific behavioral (social behavior deficits in males and increased anxiety in females) and intestinal phenotypes. In conclusion, our work demonstrates an impact of gut dysfunctions, in particular gut leakiness, on the emergence of emotional alterations. Further studies are needed to unravel the role of the gut dysbiosis in the expression of the behavioral phenotypes associated with early-life adversity.Les maladies psychiatriques présentent de fortes comorbidités avec des désordres gastrointestinaux, ce qui suggère l’existence de bases physiopathologiques communes. Une littérature abondante démontre que l’adversité précoce (infection, stress) augmente la vulnérabilité aux désordres psychiatriques à l’âge adulte. Chez le rongeur, le modèle de séparation maternelle induit chez la descendance adulte des comportements hyperanxieux associés à une hypersensibilité au stress, ainsi que des dysfonctionnements de la sphère gastrointestinale. De plus, des études récentes rapportent une hyperperméabilité de la barrière intestinale chez les ratons soumis au stress de séparation, un effet conduisant potentiellement à une dysbiose et une perturbation de la communication intestin-cerveau. Le but de ma thèse était donc d’étudier le rôle de l’axe intestin-cerveau dans la mise en place des effets à long terme du stress précoce. Nos travaux récents ont montré que certains effets à long-terme de la séparation maternelle peuvent être atténués par l’exposition des mères à un régime hyperlipidique. Dans un premier temps, nous avons testé les effets du régime hyperlipidique maternel sur le cerveau et l’intestin de ratons soumis à la séparation maternelle. Nos résultats montrent que le régime maternel hyperlipidique protège de l’augmentation de la permeabilité intestinale induite par le stress. Nous avons ensuite testé le rôle causal de la perméabilité intestinale sur les comportements émotionnels à travers une approche pharmacologique et une approche génétique. Nous rapportons 1) que la restauration de la fonction barrière de l’intestin atténue certains effets de la séparation maternelle et 2) qu’une hyperperméabilité intestinale chez des souris transgéniques non soumises à un stress produit des effets similaires à ceux de la séparation maternelle. Enfin, nous avons examiné les effets d’une adversité précoce multifactorielle sur le cerveau et l’intestin (perméabilité et microbiote) chez la descendance adulte mâle et femelle dans un modèle combinant infection prénatale et séparation maternelle. Nos résultats mettent en évidence un effet sexe très marqué sur les phénotypes comportements et intestinaux. D’autres études sont nécessaires pour identifier les mécanismes sous-tendant les effets de la perméabilité et la dysbiose intestinale sur la vulnérabilité émotionnelle associée au stress précoce

Proc Nutr Soc

The developmental period constitutes a critical window of sensitivity to stress. Indeed, early-life adversity increases the risk to develop psychiatric diseases, but also gastrointestinal disorders such as the irritable bowel syndrome at adulthood. In the past decade, there has been huge interest in the gut-brain axis, especially as regards stress-related emotional behaviours. Animal models of early-life adversity, in particular, maternal separation (MS) in rodents, demonstrate lasting deleterious effects on both the gut and the brain. Here, we review the effects of MS on both systems with a focus on stress-related behaviours. In addition, we discuss more recent findings showing the impact of gut-directed interventions, including nutrition with pre- and probiotics, illustrating the role played by gut microbiota in mediating the long-term effects of MS. Overall, preclinical studies suggest that nutritional approaches with pro- and prebiotics may constitute safe and efficient strategies to attenuate the effects of early-life stress on the gut-brain axis. Further research is required to understand the complex mechanisms underlying gut-brain interaction dysfunctions after early-life stress as well as to determine the beneficial impact of gut-directed strategies in a context of early-life adversity in human subjects

Maternal high-fat diet leads to hippocampal and amygdala dendritic remodeling in adult male offspring

Early-life exposure to calorie-dense food, rich in fat and sugar, contributes to the increasing prevalence of obesity and its associated adverse cognitive and emotional outcomes at adulthood. It is thus critical to determine the impact of such nutritional environment on neurobehavioral development. In animals, maternal high-fat diet (HFD) consumption impairs hippocampal function in adult offspring, but its impact on hippocampal neuronal morphology is unknown. Moreover, the consequences of perinatal HFD exposure on the amygdala, another important structure for emotional and cognitive processes, remain to be established. In rats, we show that adult offspring from dams fed with HFD (45% from fat, throughout gestation and lactation) exhibit atrophy of pyramidal neuron dendrites in both the CA1 of the hippocampus and the basolateral amygdala (BLA). Perinatal HFD exposure also impairs conditioned odor aversion, a task highly dependent on BLA function, without affecting olfactory or malaise processing. Neuronal morphology and behavioral alterations elicited by perinatal HFD are not associated with body weight changes but with higher plasma leptin levels at postnatal day 15 and at adulthood. Taken together, our results suggest that perinatal HFD exposure alters hippocampal and amygdala neuronal morphology which could participate to memory alterations at adulthood

Maternal high-fat diet prevents developmental programming by early life stress

Background: Anxiety disorders and depression are well documented in subjects exposed to adverse childhood events. Recently, maternal obesity and maternal consumption of high-fat diets (HFD) have been also proposed as risk factors for offspring mental health. Here, using an animal model in rats, we explored the combinatorial effects of perinatal exposure to HFD and stress in offspring. Methods: Dams were exposed to HFD throughout gestation and lactation and maternal separation (MS) was used to mimic early psychosocial stress. Results: In the prefrontal cortex (PFC) of pups, MS led to changes in the expression of several genes such as Bdnf (brain derived neurotrophic factor), 5HT-r1a (serotonin receptor 1a) and Rest4 (neuron-restrictive silencer element, repressor element 1, silencing transcription factor (Rest), splicing variant 4). Contrary to our hypothesis, perinatal HFD strongly attenuated the developmental alterations induced by MS. Furthermore, maternal HFD totally prevented the endophenotypes associated with MS in adulthood. Notably, perinatal HFD per se had no impact in the offspring. Finally, we show that HFD intake reduced anxiety and enhanced maternal care in stressed dams. Conclusions: Our results reveal a protective effect of fat on the immature brain in a context of early life stress, possibly through an anti-stress effect in dams

Physiologie et pathologie des barriers

National audienc

Maternal high fat diet and early life stress induce metabolic disturbances and enhance motivation for palatable food in offspring

National audienc

Maternal high fat diet and early life stress induce metabolic disturbances and enhance motivation for palatable food in offspring

Poste

Maternal high-fat diet and early life stress differentially modulate spine density and dendritic morphology in the medial prefrontal cortex of juvenile and adult rats

The medial prefrontal cortex (mPFC) is a key area for the regulation of numerous brain functions including stress response and cognitive processes. This brain area is also particularly affected by adversity during early life. Using an animal model in rats, we recently demonstrated that maternal exposure to a high-fat diet (HFD) prevents maternal separation (MS)-induced gene expression alterations in the developing PFC and attenuates several long-term deleterious behavioral effects of MS. In the present study, we ask whether maternal HFD could protect mPFC neurons of pups exposed to early life stress by examining dendritic morphology and spine density in juvenile [postnatal day (PND) 21] and adult rats submitted to MS. Dams were fed either a control or an HFD throughout gestation and lactation, and pups were submitted to MS from PND2 to PND14. We report that maternal HFD prevents MS-induced spine loss at PND21 and dendritic atrophy at adulthood. Furthermore, we show in adult MS rats that PFC-dependent memory extinction deficits are prevented by maternal HFD. Finally, perinatal HFD exposure reverses gut leakiness following stress in pups and seems to exert an anti-stress effect in dams. Overall, our work demonstrates that maternal HFD affects the developing brain and suggests that nutrition, possibly through gut-brain interactions, could modulate mPFC sensitivity to early stress.Environnement psychosocial précoce, empreintes biologiques et épigénétiques et état de santé à l'âge adult

Pharmacological inhibition of gut leakiness prevents the long-term effects of early-life stress in rats

National audienc