Breton B, Motin A, Billard R, Kah O, Geoffre S, Precigoux G
Gen Comp Endocrinol. 1986 Jan;61(1):109-19. doi: 10.1016/0016-6480(86)90255-8.
In fish there are few data on the gonadotropin-releasing hormone (Gn-RH) neurosecretory activity, which could explain long- and short-term variations of the gonadotropin secretion. There is no biological species specificity between mammal and fish Gn-RH; although there is a structural difference, they are, on the contrary, characterized by a high immunological specificity which does not allow measurement of fish Gn-RH using radioimmunoassay for LH-RH. We have synthesized salmon Gn-RH according to the formula recently proposed by Sherwood (N. Sherwood, L. Eiden, M. Brownstein, J. Spies, J. Rivier, and W. Vale, 1983. Proc. Natl. Acad. Sci. USA 80, 2794-2798). Its activity has been tested by its ability to stimulate the gonadotropin hormone (GtH) secretion in vivo in testosterone-implanted juvenile rainbow trout, and for the recognition of synthesized Gn-RH (s-Gn-RH) perykaria by a specific antibody raised against the s-Gn-RH in regions of the brain described as containing LH-RH immunoreactive-like material. A radioimmunoassay has been developed for the salmon Gn-RH, and its specificity to measure trout Gn-RH has been tested. Using this assay, the brain and pituitary Gn-RH contents have been measured throughout the final phases of maturation and ovulation. Brain Gn-RH increases from the end of vitellogenesis (8.9 +/- 0.76 ng/brain) to ovulation (more than 15 ng/brain). Pituitary Gn-RH is lower (1.58 +/- 0.69 ng/pituitary) at the end of vitellogenesis and follows a similar profile as in the brain, except for a significant decrease just prior the beginning of oocyte maturation. The correlations between Gn-RH levels and GtH pituitary and plasma levels show that total brain Gn-RH is never correlated to the GtH, suggesting that the increase in the brain Gn-RH content is related to a Gn-RH system closely related to maturation and ovulation, which remains to be investigated. On the contrary, pituitary Gn-RH levels are well correlated with pituitary and plasma GtH levels, indicating that pituitary Gn-RH levels might represent a good index of the Gn-RH neurosecretory activity in the fish hypothalamohypophysial complex, given the absence of a portal system in teleost.
关于促性腺激素释放激素(Gn-RH)的神经分泌活动,鱼类方面的数据较少,而这一活动可以解释促性腺激素分泌的长期和短期变化。哺乳动物和鱼类的Gn-RH之间不存在生物学物种特异性;尽管存在结构差异,但相反的是,它们具有高度的免疫特异性,这使得无法使用促黄体生成素释放激素(LH-RH)的放射免疫测定法来测量鱼类的Gn-RH。我们根据舍伍德最近提出的公式(N. 舍伍德、L. 艾登、M. 布朗斯坦、J. 斯皮斯、J. 里维埃和W. 瓦尔,1983年。《美国国家科学院院刊》80,2794 - 2798)合成了鲑鱼Gn-RH。通过其在植入睾酮的幼年虹鳟体内刺激促性腺激素(GtH)分泌的能力,以及在被描述为含有LH-RH免疫反应样物质的脑区中,用针对合成Gn-RH(s-Gn-RH)产生的特异性抗体对合成Gn-RH(s-Gn-RH)神经元周体的识别能力,对其活性进行了测试。已经开发出一种针对鲑鱼Gn-RH的放射免疫测定法,并测试了其测量鳟鱼Gn-RH的特异性。使用这种测定法,在成熟和排卵的最后阶段测量了脑和垂体中的Gn-RH含量。脑Gn-RH从卵黄发生末期(8.9±0.76纳克/脑)增加到排卵时(超过15纳克/脑)。垂体Gn-RH在卵黄发生末期较低(1.58±0.69纳克/垂体),并且与脑中的情况类似,只是在卵母细胞成熟开始前有显著下降。Gn-RH水平与垂体和血浆中GtH水平之间的相关性表明,脑Gn-RH总量与GtH从未相关,这表明脑Gn-RH含量的增加与一个与成熟和排卵密切相关的Gn-RH系统有关,这仍有待研究。相反,垂体Gn-RH水平与垂体和血浆GtH水平密切相关,这表明鉴于硬骨鱼没有门脉系统,垂体Gn-RH水平可能是鱼类下丘脑 - 垂体复合体中Gn-RH神经分泌活动的一个良好指标。
