Depressive behavior and activation of the orexin/hypocretin system.

The orexin/hypocretin peptide signaling system plays a neuromodulatory role in motivation and stress; two critical components of depression. Although work has been done to identify links between orexin and depression, few specific neuroanatomical associations have been made. These studies have not investigated the relationship between orexin and orexin receptor expression in specific brain regions associated with this disorder. To address this, we examined immobility during the forced swim test (FST) in mice, a commonly used measure of depressive behavior. We analyzed the variation in FST immobility with the distribution of orexin and its receptor mRNA. We found that animals that exhibited more robust depressive behavior had greater or lesser orexin system expression that depended on the limbic brain region analyzed. In the hippocampus there was a negative correlation between orexin expression and FST immobility. Animals that displayed relatively more depressive behavior had lower hippocampal expression of Orexin A (OrxA). In the amygdala, there was a curvilinear relationship between OrxA and FST performance. In addition there was a positive correlation with amygdalar Type I orexin receptor (Orx1) mRNA and depressive behavior. Despite the differences in limbic orexin expression, there was no correlation between immobility and hypothalamic orexin neuron activation as measured by c-Fos. Overall, more severe depressive behavior was associated with reduced hippocampal orexin expression, contrasted with increased orexin plus Orx1 receptor mRNA expression in the amygdala. This divergent pattern between the hippocampus and amygdala mirrors a neurobiological theme seen in depression resulting from reduced hippocampal, but increased amygdalar, size and function.

Contrasting hippocampal and amygdalar expression of genes related to neural plasticity during escape from social aggression.

Social subjugation has widespread consequences affecting behavior and underlying neural systems. We hypothesized that individual differences in stress responsiveness were associated with differential expression of neurotrophin associated genes within the hippocampus and amygdala. To do this we examined the brains of hamsters placed in resident/intruder interactions, modified by the opportunity to escape from aggression. In the amygdala, aggressive social interaction stimulated increased BDNF receptor TrK(B) mRNA levels regardless of the ability to escape the aggressor. In contrast, the availability of escape limited the elevation of GluR(1) AMPA subunit mRNA. In the hippocampal CA(1), the glucocorticoid stress hormone, cortisol, was negatively correlated with BDNF and TrK(B) gene expression, but showed a positive correlation with BDNF expression in the DG. Latency to escape the aggressor was also negatively correlated with CA(1) BDNF expression. In contrast, the relationship between amygdalar TrK(B) and GluR(1) was positive with respect to escape latency. These results suggest that an interplay of stress and neurotrophic systems influences learned escape behavior. Animals which escape faster seem to have a more robust neurotrophic profile in the hippocampus, with the opposite of this pattern in the amygdala. We propose that changes in the equilibrium of hippocampal and amygdalar learning result in differing behavioral stress coping choices.