All organisms possess innate behavioural and physiological programmes that ensure survival. In order to have maximum adaptive benefit, these programmes must be sufficiently flexible to account for changes in the environment. Here we show that hypothalamic CRH neurons orchestrate an environmentally flexible repertoire of behaviours that emerge after acute stress in mice. Optical silencing of CRH neurons disrupts the organization of individual behaviours after acute stress. These behavioural patterns shift according to the environment after stress, but this environmental sensitivity is blunted by activation of PVN CRH neurons. These findings provide evidence that PVN CRH cells are part of a previously unexplored circuit that matches precise behavioural patterns to environmental context following stress. Overactivity in this network in the absence of stress may contribute to environmental ambivalence, resulting in context-inappropriate behavioural strategies.
Stress and anxiety have intertwined behavioral and neural underpinnings. These commonalities are critical for understanding each state, as well as their mutual interactions. Grasping the mechanisms underlying this bidirectional relationship will have major clinical implications for managing a wide range of psychopathologies. After briefly defining key concepts for the study of stress and anxiety in pre-clinical models, we present circuit, as well as cellular and molecular mechanisms involved in either or both stress and anxiety. First, we review studies on divergent circuits of the basolateral amygdala (BLA) underlying emotional valence processing and anxiety-like behaviors, and how norepinephrine inputs from the locus coeruleus (LC) to the BLA are responsible for acute-stress induced anxiety. We then describe recent studies revealing a new role for mitochondrial function within the nucleus accumbens (NAc), defining individual trait anxiety in rodents, and participating in the link between stress and anxiety. Next, we report findings on the impact of anxiety on reward encoding through alteration of circuit dynamic synchronicity. Finally, we present work unravelling a new role for hypothalamic corticotropin-releasing hormone (CRH) neurons in controlling anxiety-like and stress-induce behaviors. Altogether, the research reviewed here reveals circuits sharing subcortical nodes and underlying the processing of both stress and anxiety. Understanding the neural overlap between these two psychobiological states, might provide alternative strategies to manage disorders such as post-traumatic stress disorder (PTSD).
Stress can trigger enduring changes in neural circuits and synapses. The behavioral and hormonal consequences of stress can also be transmitted to others, but whether this transmitted stress has similar effects on synapses is not known. We found that authentic stress and transmitted stress in mice primed paraventricular nucleus of the hypothalamus (PVN) corticotropin-releasing hormone (CRH) neurons, enabling the induction of metaplasticity at glutamate synapses. In female mice that were subjected to authentic stress, this metaplasticity was diminished following interactions with a naive partner. Transmission from the stressed subject to the naive partner required the activation of PVN CRH neurons in both subject and partner to drive and detect the release of a putative alarm pheromone from the stressed mouse. Finally, metaplasticity could be transmitted sequentially from the stressed subject to multiple partners. Our findings demonstrate that transmitted stress has the same lasting effects on glutamate synapses as authentic stress and reveal an unexpected role for PVN CRH neurons in transmitting distress signals among individuals.
Post-traumatic stress disorder (PTSD) patients show cognitive deficits, but it is unclear whether these are a consequence of the pathology or a pre-existing factor of vulnerability to PTSD. Animal models may help to demonstrate whether or not exposure to certain stressors can actually induce long-lasting (LL; days) impairment of hippocampus-dependent memory tasks and to characterize neurobiological mechanisms. Adult male rats were exposed to 2-h immobilization on boards (IMO), a severe stressor, and spatial learning in the Morris water maze (MWM) was studied days later. Exposure to IMO did not modify learning or short-term memory in the MWM when learning started 3 or 9 days after IMO, but stressed rats did show impaired long-term memory at both times, in accordance with the severity of the stressor. New treatments to prevent PTSD symptoms are needed. Thus, considering the potential protective role of brain-derived neurotrophic factor (BDNF) on hippocampal function, 7,8-dihydroxyflavone (7,8-DHF), a recently characterized agonist of the BDNF receptor TrkB, was given before or after IMO in additional experiments. Again, exposure to IMO resulted in LL deficit in long-term memory, and such impairment was prevented by the administration of 7,8-DHF either 2 h prior IMO or 8 h after the termination of IMO. The finding that IMO-induced impairment of spatial memory was prevented by pharmacological potentiation of TrkB pathway with 7,8-DHF even when the drug was given 8 h after IMO suggests that IMO-induced impairment is likely to be a LL process that is strongly dependent on the integrity of the BDNF-TrkB system and is susceptible to poststress therapeutic interventions. 7,8-DHF may represent a new therapeutic approach for early treatment of subjects who have suffered traumatic experiences.
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