Browsing by Subject "parvalbumin"

Chronic stress has been linked to the pathogenesis of various disorders, such as generalized anxiety disorder, depression, and post-traumatic stress disorder (PTSD). Stress-induced hyperexcitability of the basolateral amygdala (BLA) has implications in anxiety-like behavior. Promising evidence points to the direction of GluK1 subunit containing kainate receptors (KARs) having a role in the modulation of GABAergic transmission in the lateral amygdala (LA). The aim of the present study was to investigate whether dysfunction of KARs contribute to stress-induced amygdala hyperexcitability and anxiogenesis in mice. Chronic restraint stress (CRS) is an animal model simulating chronic psychological stress. An in situ hybridization experiment was performed to investigate how CRS affects expression levels of GluK1 in the different neuronal populations in the LA. These data show that CRS leads to downregulation of GluK1 expression in the parvalbumin-positive (PV+) interneurons specifically. Patch clamp recordings of spontaneous inhibitory postsynaptic currents showed that CRS did not affect synaptic GABAergic transmission to the principal neurons in the LA. Lastly, conditional knock-out (cKO) mice that have the Grik1 gene knocked out selectively in the PV-expressing interneurons showed no change in anxiety-like behavior after CRS while their wild-type counterparts demonstrated an increase in anxiety-like behavior observable in the elevated plus maze test. Thus, ablation of GluK1 in PV+ interneurons affects the stress-induced anxiogenesis. Due to low number of animals, it cannot be confirmed yet whether the deletion leads to stress resilience or a phenotype where even regular handling is an aversive experience comparable to physical restraint. GluK1 KAR modulation of PV+ interneuron excitability and its susceptibility to stress-related alterations is only a recently discovered phenomenon, and even though this study provides some insight into the underlying mechanism, further research is needed. Systematic characterization of the mechanism could provide a novel tool for understanding and treating stress-related pathological anxiety, possibly helping patients suffering from anxiety disorders resistant to current treatments available.

As the most common mental disorder, anxiety disorders present a major burden to healthcare worldwide and a challenging problem to overcome for the ones suffering from it. Recently, researchers have started to recognize that the relationship between sleep and anxiety disorders is bidirectional; disturbed sleep is a potential risk factor for the progression of anxiety and anxiety can lead to sleep disturbances. However, the neural mechanisms underlying anxiety and sleep problems are still poorly recognized. In this study, we used a chronic sleep fragmentation (SF) paradigm to investigate how disturbed sleep alters anxiety-like behavior in mice and what are the potential underlying neuronal mechanisms. This model was chosen because we wanted to focus on a common form of disturbed sleep in humans rather than total sleep deprivation. We measured anxiety-like behavior in the light-dark box and open field tests right after the 2-week SF period and again after a week of recovery. Additionally, we performed immunohistochemical analysis to study prolonged cell activity (transcription factor ∆FosB), parvalbumin (PV) interneurons and perineuronal net (PNN) structures in the medial prefrontal cortex (mPFC) of the mice. Changes in mPFC activity and related brain areas are associated to anxiety in humans and anxiety-like behavior in rodents alike. Similarly, changes in PV interneurons and PNNs, that regulates PV cell function, are associated to anxiety-like behavior. However, PV interneurons and PNNs have not been previously studied in a setting that combines sleep fragmentation and anxiety-like behavior. We found that chronic SF increases anxiety-like behavior in female mice and that this effect persists at least for a week. Conversely, we did not observe significant increase in anxiety-like behavior in male mice. Both female and male mice showed decrease in ∆FosB in the mPFC suggesting that SF treated mice had lower overall levels of cell activity. Similarly, we found that SF treated mice had decreased PV interneuron intensity in both sexes which could indicate changes in the cell activity. However, the pattern of changes in the IHC results was not identical in males and females. Based on the IHC results, we suggest that SF affects neuronal processes in both sexes but the disparity in them could explain the difference in the behavioral effect. This thesis shows that disturbed sleep can lead to increased anxiety-like behavior in rodent models and recognizes potential targets to study the mechanisms behind the phenomena.