性腺类固醇和肾上腺类固醇通过涉及N-甲基-D-天冬氨酸(NMDA)受体的细胞机制调节海马体的神经化学和结构可塑性。
Gonadal and adrenal steroids regulate neurochemical and structural plasticity of the hippocampus via cellular mechanisms involving NMDA receptors.
作者信息
McEwen B S
机构信息
Laboratory of Neuroendocrinology, Rockefeller University, New York, New York 10021, USA.
出版信息
Cell Mol Neurobiol. 1996 Apr;16(2):103-16. doi: 10.1007/BF02088170.
Abstract
- The hippocampus is an important brain structure for working and spatial memory in animals and humans, and it is also a vulnerable as well as plastic brain structure as far as sensitivity to epilepsy, ischemia, head trauma, stress, and aging. 2. The hippocampus is also a target brain area for the actions of hormones of the steroid/thyroid hormone family, which traditionally have been thought to work by regulating gene expression. "Genomic" actions of steroid hormones involve intracellular receptors, whereas "nongenomic" effects of steroids involve putative cell surface receptors. Although this distinction is valid, it does not go far enough in addressing the variety of mechanisms that steroid hormones use to produce their effects on cells. This is because cell surface receptors may signal changes in gene expression, while genomic actions sometimes affect neuronal excitability, often doing so quite rapidly. 3. Moreover, steroid hormones and neurotransmitters may operate together to produce effects, and sometimes these effects involve collaborations between groups of neurons. For example, a number of steroid actions in the hippocampus involve the coparticipation of excitatory amino acids. These interactions are evident for the regulation of synaptogenesis by estradiol in the CA1 pyramidal neurons of hippocampus and for the induction of dendritic atrophy of CA3 neurons by repeated stress as well as by glucocorticoid injections. In addition, neurogenesis in the adult and developing dentate gyrus is "contained" by adrenal steroids as well as by excitatory amino acids. In each of these three examples, NMDA receptors are involved. 4. These results not only point to a high degree of interdependency between certain neurotransmitters and the actions of steroid hormones, but also emphasize the degree to which structural plasticity is an important aspect of steroid hormone action in the adult as well as developing nervous system.
摘要
- 海马体是动物和人类工作记忆与空间记忆的重要脑结构,就对癫痫、缺血、头部创伤、压力和衰老的敏感性而言,它也是一个易损且具有可塑性的脑结构。2. 海马体也是类固醇/甲状腺激素家族激素作用的目标脑区,传统上认为这些激素通过调节基因表达发挥作用。类固醇激素的“基因组”作用涉及细胞内受体,而类固醇的“非基因组”作用涉及假定的细胞表面受体。尽管这种区分是有效的,但在解释类固醇激素对细胞产生作用的各种机制方面还远远不够。这是因为细胞表面受体可能会发出基因表达变化的信号,而基因组作用有时会影响神经元兴奋性,而且往往作用相当迅速。3. 此外,类固醇激素和神经递质可能共同发挥作用产生效应,有时这些效应涉及神经元群体之间的协作。例如,海马体中的一些类固醇作用涉及兴奋性氨基酸的共同参与。这些相互作用在海马体CA1锥体神经元中雌二醇对突触发生的调节、重复应激以及糖皮质激素注射对CA3神经元树突萎缩的诱导中很明显。此外,成年和发育中的齿状回中的神经发生受到肾上腺类固醇以及兴奋性氨基酸的“抑制”。在这三个例子中,NMDA受体都参与其中。4. 这些结果不仅表明某些神经递质与类固醇激素作用之间存在高度相互依存关系,还强调了结构可塑性在成年及发育中的神经系统中作为类固醇激素作用重要方面的程度。
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