Depression is a multifactorial disorder shaped by genetic, psychosocial, and biological influences, with hypotheses ranging from monoamine deficiency and neuroplasticity deficits to inflammation and stress-induced dysregulation. St. John's wort (Hypericum perforatum L.) has long been used as an herbal antidepressant and is supported by clinical evidence for efficacy and safety in mild-to-moderate depression. While its multimodal mechanisms have been linked to neurotransmitter reuptake inhibition, neuroendocrine regulation, and modulation of neuroplasticity, recent findings suggest an additional role at the membrane level. Emerging lipidomic studies highlight that Ze 117, a low-hyperforin H. perforatum extract, counteracts stress- and glucocorticoid-induced increases in membrane fluidity by modulating lipid composition and cholesterol metabolism. These effects normalize receptor mobility and signal transduction, particularly of β1-adrenoceptors, and modulate glycerophospholipid metabolism in both cellular and animal models. Such membrane-stabilizing properties may represent a novel mechanistic pathway complementing classical neurochemical actions. This review revisits the mechanisms of St. John's wort with a special focus on its impact on membrane lipids, positioning lipidomics as a promising tool for elucidating antidepressant activity. These insights may open avenues toward personalized therapeutic strategies in depression.
Keywords: Hypericum perforatum; St. John’s wort; Ze 117; depression; lipidomics; membrane fluidity; neuroplasticity; phospholipids.