Distinct Molecular Responses to Ketamine and Imipramine in Cortical and Striatal Regions Following Acute Swim Stress
Veronica Begni, Floriana de Cillis, Natascha Pfeiffer, Steven Roger Talbot, Peter Gass, Annamaria Cattaneo, Marco Andrea Riva, Anne Stephanie Mallien
Biomolecules March 24, 2026 Peer reviewed DOI: 10.3390/biom16040484 via OpenAlex
Summary
Imipramine and ketamine, two antidepressants, show different effects on brain responses to acute stress in mice. Imipramine reduced stress-related activation in the cortex and striatum, while ketamine maintained neuronal activation during stress. Both drugs facilitated active coping behaviors but through different molecular pathways. These findings suggest that classical and rapid-acting antidepressants target distinct mechanisms in the brain, particularly in cortical and striatal regions.
Study at a glance
| Population | mice exposed to acute swim stress |
|---|---|
| Key finding | Imipramine dampened cortical and striatal cFOS expression, while ketamine preserved stress-evoked neuronal activation. |
Abstract
Pharmacological antidepressant treatments alter the molecular and functional reactivity of stress-sensitive neural networks. However, how classical versus rapid-acting antidepressants differentially modulate acute stress-induced transcriptional responses across brain regions remains unclear. Here, we compared imipramine and ketamine in mice exposed to acute swim stress, assessing transcriptional adaptations across the frontal cortex, hippocampus, and striatum. Swim stress induced significant widespread activation of cFOS, which led to drug-specific modulations: imipramine primarily significantly dampened cortical and striatal cFOS expression, whereas ketamine preserved stress-evoked neuronal activation. In contrast, hippocampal activation was significantly robust but largely unaffected, indicating that acute antidepressant drug effects during stress coping preferentially target cortical and striatal plasticity mechanisms. In contrast, BDNF expression was altered only within the striatal region, where imipramine attenuated the stress-related increase in BDNF expression. Statistical analysis of behavioral outcomes during the swim stress confirmed a shared facilitation of active coping, yet these similar outcomes emerged from distinct molecular programs. Together, the data demonstrate that the treatment effects of the two substances diverge mechanistically, revealing cortical and striatal transcriptional signatures of classical versus rapid-acting antidepressant action. While these findings suggest potential translational relevance for understanding distinct mechanisms, further studies in humans are required to validate these signatures and their clinical implications.