Valentine Gerald W, Sanacora Gerard
Yale University, Department of Psychiatry, CNRU, 34 Park Street, New Haven, CT 06508, USA.
Biochem Pharmacol. 2009 Sep 1;78(5):431-9. doi: 10.1016/j.bcp.2009.04.008. Epub 2009 Apr 17.
Accumulating evidence indicates that dysfunction in amino acid neurotransmission contributes to the pathophysiology of depression. Consequently, the modulation of amino acid neurotransmission represents a new strategy for antidepressant development. While glutamate receptor ligands are known to have antidepressant effects, mechanisms regulating glutamate cycling and metabolism may be viable drug targets as well. In particular, excitatory amino acid transporters (EAATs) that are embedded in glial processes constitute the primary means of clearing extrasynaptic glutamate. Therefore, the decreased glial number observed in preclinical stress models, and in postmortem tissue from depressed patients provides intriguing, yet indirect evidence for a role of disrupted glutamate homeostasis in the pathophysiology of depression. More direct evidence for this hypothesis comes from studies using magnetic resonance spectroscopy (MRS), a technique that non-invasively measures in vivo concentrations of glutamate and other amino acids under different experimental conditions. Furthermore, when combined with the infusion of (13)C-labeled metabolic precursors, MRS can measure flux through discrete metabolic pathways. This approach has recently shown that glial amino acid metabolism is reduced by chronic stress, an effect that provides a link between environmental stress and the decreased EAAT activity observed under conditions of increased oxidative stress in the brain. Furthermore, administration of riluzole, a drug that enhances glutamate uptake through EAATs, reversed this stress-induced change in glial metabolism. Because riluzole has antidepressant effects in both animal models and human subjects, it may represent the prototype for a novel class of antidepressants with the modulation of glial physiology as a primary mechanism of action.
越来越多的证据表明,氨基酸神经传递功能障碍与抑郁症的病理生理学有关。因此,调节氨基酸神经传递是抗抑郁药研发的一种新策略。虽然已知谷氨酸受体配体具有抗抑郁作用,但调节谷氨酸循环和代谢的机制也可能是可行的药物靶点。特别是,嵌入胶质细胞突起中的兴奋性氨基酸转运体(EAATs)是清除突触外谷氨酸的主要方式。因此,在临床前应激模型以及抑郁症患者的尸检组织中观察到的胶质细胞数量减少,为谷氨酸稳态破坏在抑郁症病理生理学中的作用提供了有趣但间接的证据。这一假设的更直接证据来自使用磁共振波谱(MRS)的研究,该技术可在不同实验条件下非侵入性地测量体内谷氨酸和其他氨基酸的浓度。此外,当与注入(13)C标记的代谢前体相结合时,MRS可以测量通过离散代谢途径的通量。最近的研究表明,慢性应激会降低胶质细胞的氨基酸代谢,这一效应在环境应激与大脑氧化应激增加条件下观察到的EAAT活性降低之间建立了联系。此外,给予利鲁唑(一种通过EAATs增强谷氨酸摄取的药物)可逆转这种应激诱导的胶质细胞代谢变化。由于利鲁唑在动物模型和人类受试者中均具有抗抑郁作用,它可能代表了一类新型抗抑郁药的原型,其主要作用机制是调节胶质细胞生理功能。