Translational psychiatry
November 18, 2025
Jenessa N Johnston, Peixiong Yuan, Bashkim Kadriu et al.
2 citations
In neurons derived from induced pluripotent stem cells of five women with treatment-resistant depression (average age 40.2 years), both the glycoprotein reelin and the ketamine metabolite (2R,6R)-hydroxynorketamine increased expression of several synaptic proteins (GluA1, PSD-95, Dab1, Synapsin I, and p-ERK) within one hour, with effects declining by 24 hours. Gene expression changes were similar for both compounds, though only reelin upregulated mTORC1 signaling. The findings suggest that iPSC-derived neurons may serve as a useful in vitro model for studying treatment-resistant depression and testing potential therapeutics.
Journal of neuroendocrinology
January 1, 2026
Hiroe Hu, Yoojin Lee, Alaina N Tillman et al.
1 citation
People with both major depression and post-traumatic stress disorder (PTSD) have lower baseline levels of copeptin, a stable marker of vasopressin secretion, and a blunted reduction in copeptin after a single low-dose ketamine infusion compared to those with depression alone. Copeptin levels were unrelated to depression diagnosis or symptom severity of depression, anxiety, PTSD, anhedonia, suicidal ideation, or childhood trauma, but higher copeptin was linked to verbal aggression, an association weakened by PTSD. These findings point to a possible biological subtype of reduced vasopressin activity in co-occurring depression and PTSD, suggesting copeptin may serve as a peripheral biomarker for central vasopressin-driven circuits in neuropsychiatric disorders.
Research square
February 12, 2026
Jenessa Johnston, Greg Jones, Shiyong Peng et al.
Rapid-acting antidepressants such as ketamine and psychedelics share common downstream effects on gene expression in human cortical neurons, despite targeting different initial receptors. Using stem cells from people with treatment-resistant depression and healthy volunteers, neurons were treated with several compounds. After 6 and 24 hours, gene activity was highly correlated across all drugs, converging on pathways related to inflammation, mTORC1 signaling, and cell growth. One compound, HNK, increased gene activity in excitatory neurons and decreased it in inhibitory neurons. These gene changes matched protein changes in spinal fluid from people given ketamine, supporting the model's relevance for studying antidepressant mechanisms.