Nagahama Y, Yoshikuni M, Yamashita M, Tokumoto T, Katsu Y
Department of Developmental Biology, National Institute for Basic Biology, Okazaki, Japan.
Curr Top Dev Biol. 1995;30:103-45. doi: 10.1016/s0070-2153(08)60565-7.
This chapter has briefly reviewed the current status of investigations on the hormonal regulation of oocyte growth and maturation in fish (see Figs. 4 and 9). Pituitary gonadotropins are of primary importance in triggering these processes in fish oocytes. In both cases, however, the actions of gonadotropins are not direct, but are mediated by the follicular production of steroidal mediators, estradiol-17 beta (oocyte growth) and 17 alpha,20 beta-DP or 20 beta-S (oocyte maturation). Investigators have established that both estradiol-17 beta and 17 alpha,20 beta-DP are biosynthesized by salmonid ovarian follicles via an interaction of two cell layers, the thecal and granulosa cell layers (two-cell-type model). The granulosa cell layers are the site of production of these two steroidal mediators, but their production depends on the provision of precursor steroids by the thecal cell layers. A distinct steroidogenic shift from estradiol-17 beta to 17 alpha,20 beta-DP, occurring in salmonid ovarian follicles immediately prior to oocyte maturation, is a prerequisite for the growing oocytes to enter the maturation stage, and requires a complex and integrated network of gene regulation involving cell specificity, hormonal regulation, and developmental patterning. The cDNAs for most of the steroidogenic enzymes responsible for estradiol-17 beta and 17 alpha,20 beta-DP biosynthesis have been cloned from rainbow trout ovaries. Our next task is to determine how gonadotropin and other factors act on ovarian follicle cells to turn the expression of these specific genes on and off at specific times during oocyte growth and maturation. Increasing evidence now suggests that a variety of neuromodulatory, autocrine, and paracrine factors may also be involved in the regulation of steroidogenesis in fish ovarian follicles. Molecular biological technologies should be applied to identify these substances. Of considerable interest is the finding that MIH, unlike most steroid hormones, acts on its receptors at the surface of oocytes. Further studies of the association of the MIH-MIH receptor complex with a Gi protein, probably resulting in the inactivation of adenylate cyclase, should lead to a discovery of a new mechanism of steroid hormone action. The early steps following MIH action involve the formation of the major cytoplasmic mediator of MIH, MPF. Fish MPF, like that of Xenopus and starfish, consists of two components: cdc2 kinase and cyclin B. Nevertheless, the mechanism of MIH-induced MPF activation in fish oocytes differs from that in Xenopus and starfish because the appearance of cyclin B protein is a crucial step for 17 alpha,20 beta-DP-induced oocyte maturation in fish.(ABSTRACT TRUNCATED AT 400 WORDS)
本章简要回顾了鱼类卵母细胞生长和成熟的激素调节研究现状(见图4和图9)。垂体促性腺激素在触发鱼类卵母细胞的这些过程中至关重要。然而,在这两种情况下,促性腺激素的作用都不是直接的,而是由卵泡产生的甾体介质介导的,即17β-雌二醇(卵母细胞生长)和17α,20β-双羟孕酮或20β-羟孕酮(卵母细胞成熟)。研究人员已经确定,17β-雌二醇和17α,20β-双羟孕酮都是由鲑科鱼类卵巢卵泡通过两层细胞,即膜细胞层和颗粒细胞层的相互作用生物合成的(双细胞类型模型)。颗粒细胞层是这两种甾体介质的产生部位,但其产生取决于膜细胞层提供的前体类固醇。在鲑科鱼类卵巢卵泡中,紧接卵母细胞成熟之前发生的从17β-雌二醇到17α,20β-双羟孕酮的明显的类固醇生成转变,是正在生长的卵母细胞进入成熟阶段的先决条件,并且需要一个涉及细胞特异性、激素调节和发育模式形成的复杂且整合的基因调控网络。负责17β-雌二醇和17α,20β-双羟孕酮生物合成的大多数类固醇生成酶的cDNA已从虹鳟卵巢中克隆出来。我们的下一个任务是确定促性腺激素和其他因素如何作用于卵巢卵泡细胞,以在卵母细胞生长和成熟的特定时间开启和关闭这些特定基因的表达。现在越来越多的证据表明,多种神经调节、自分泌和旁分泌因子也可能参与鱼类卵巢卵泡中类固醇生成的调节。应应用分子生物学技术来鉴定这些物质。一个相当有趣的发现是,与大多数类固醇激素不同,促成熟激素(MIH)作用于卵母细胞表面的受体。对MIH-MIH受体复合物与Gi蛋白的关联进行进一步研究,可能会导致腺苷酸环化酶失活,这应该会发现一种新的类固醇激素作用机制。MIH作用后的早期步骤涉及MIH的主要细胞质介质成熟促进因子(MPF)的形成。鱼类的MPF与非洲爪蟾和海星的MPF一样,由两个成分组成:细胞周期蛋白依赖性激酶2(cdc2激酶)和细胞周期蛋白B。然而,鱼类卵母细胞中MIH诱导的MPF激活机制与非洲爪蟾和海星不同,因为细胞周期蛋白B蛋白的出现是17α,20β-双羟孕酮诱导鱼类卵母细胞成熟的关键步骤。(摘要截选至400字)
