Celotti F, Melcangi R C, Martini L
Department of Endocrinology, University of Milan, Italy.
Front Neuroendocrinol. 1992 Apr;13(2):163-215.
All the classes of hormonal steroids physiologically produced in the body (androgens, estrogens, progestagens, and corticosteroids) are able to exert important effects on the brain, but the mechanisms of their actions are not always well understood. Steroids may interact with intracellular receptors to activate the genome, but some of their effects are probably extragenomic and involve interactions with cellular membranes. Moreover, not all the steroids act always in their native molecular form; a large group of them must actually be transformed into "active" metabolites. This may occur at the level of their respective target structures. For example, androgens are metabolized in the brain into estrogens and into 5 alpha-reduced androgens, like 5 alpha-androstan-17 beta-ol-3-one (dihydrotestosterone; DHT) and 5 alpha-androstan-3 alpha, 17 beta-diol (3 alpha-diol). Progesterone, and possibly corticosteroids, may also be transformed into their corresponding 5 alpha-reduced metabolites. Also the cellular target (neurons and/or glial cells) of the hormonal steroids in the brain is not always clear. This review analyzes in detail one of the two major enzymatic systems that transform steroids in the brain, namely the 5 alpha-reductase-3 alpha-(3 beta)-hydroxysteroid dehydrogenase pathway. An active 5 alpha-reductase-3 alpha-hydroxysteroid dehydrogenase system is widely distributed in practically all CNS structures in all phases of development. In the brain, this enzymatic system is not regulated by castration or sex steroid administration; furthermore, neural inputs seem to be ineffective at the hypothalamic level. A recent interesting finding is the presence of high concentrations of the 5 alpha-reductase in the white matter. This probably is due to the fact that the white matter is particularly rich in myelin membranes, with which the enzymatic activity appears to be associated. An active 5 alpha-reductase activity has also been shown to be present in peripheral myelinated nerves. The localization in myelin membranes may suggest a possible involvement of 5 alpha-reduced metabolites of the different steroids in the process of myelination. The presence of the 5 alpha-reductase was analyzed in neurons, astrocytes, and oligodendrocytes isolated from the brains of male rats, as well as in neurons and glial cells grown in culture. Neurons appear to be more active than glial cells in converting testosterone into DHT. Only neurons possess aromatase activity.(ABSTRACT TRUNCATED AT 400 WORDS)
体内生理产生的所有激素类甾体(雄激素、雌激素、孕激素和皮质类固醇)都能够对大脑产生重要影响,但其作用机制并不总是被充分理解。甾体可能与细胞内受体相互作用以激活基因组,但它们的一些作用可能是基因组外的,涉及与细胞膜的相互作用。此外,并非所有甾体都始终以其天然分子形式发挥作用;其中很大一部分实际上必须转化为“活性”代谢产物。这可能发生在其各自的靶结构水平。例如,雄激素在大脑中代谢为雌激素以及5α-还原雄激素,如5α-雄甾烷-17β-醇-3-酮(双氢睾酮;DHT)和5α-雄甾烷-3α,17β-二醇(3α-二醇)。孕酮以及可能的皮质类固醇也可能转化为其相应的5α-还原代谢产物。大脑中激素类甾体的细胞靶标(神经元和/或神经胶质细胞)也并不总是明确的。本综述详细分析了大脑中转化甾体的两个主要酶系统之一,即5α-还原酶-3α-(3β)-羟基甾体脱氢酶途径。一个活性5α-还原酶-3α-羟基甾体脱氢酶系统广泛分布于发育各阶段几乎所有的中枢神经系统结构中。在大脑中,该酶系统不受去势或性甾体给药的调节;此外,神经输入在下丘脑水平似乎无效。最近一个有趣的发现是白质中存在高浓度的5α-还原酶。这可能是因为白质中富含髓鞘膜,而酶活性似乎与之相关。活性5α-还原酶活性也已在周围有髓神经中被证明存在。在髓鞘膜中的定位可能表明不同甾体的5α-还原代谢产物可能参与了髓鞘形成过程。对从雄性大鼠大脑中分离出的神经元、星形胶质细胞和少突胶质细胞以及培养的神经元和神经胶质细胞中的5α-还原酶进行了分析。在将睾酮转化为DHT方面,神经元似乎比神经胶质细胞更活跃。只有神经元具有芳香化酶活性。(摘要截取自400字)
