Dissen G A, Hirshfield A N, Malamed S, Ojeda S R
Division of Neuroscience, Oregon Regional Primate Research Center/Oregon Health Sciences University, Beaverton 97006-3499, USA.
Endocrinology. 1995 Oct;136(10):4681-92. doi: 10.1210/endo.136.10.7664689.
An emerging body of evidence suggests that neurotrophins not only promote neuronal survival and differentiation, but can also target nonneuronal cells for their actions. Neurotrophins initiate their biological effects by binding to cell membrane tyrosine kinase receptors of the trk protooncogene family. In addition, all neurotrophins recognize with similar affinity a different receptor molecule known as p75 nerve growth factor receptor (p75 NGFR) or low affinity NGFR, which appears to interact with the trk receptors to potentiate their response to neurotrophins. The mature mammalian ovary has been shown to synthesize several neurotrophins, including nerve growth factor (NGF), neurotrophin 3 (NT-3), and neurotrophin 4/5 (NT-4/5). The ovary also expresses some of the neurotrophin receptors, including p75 NGFR, trkB [the receptor for NT-4/5 and brain-derived neurotropic factor (BDNF)], and trkA (the NGF receptor). The present experiments were undertaken to determine whether neurotrophins and their receptors are expressed at the time of definitive ovarian histogenesis, and whether any of them exhibit a developmental pattern of expression related to the completion of folliculogenesis. Immunohistochemical identification of p75 NGFR in rat embryonic ovaries revealed that the receptor is predominantly expressed in mesenchymal cells. By gestational day 18, these cells have formed pockets that enclose presumptive pregranulosa cells and groups of oocytes into ovigerous cords. Immediately after birth, the ovigerous cords are subdivided, resulting in the abrupt formation of primordial follicles between 24-48 h after birth. Consistent with these observations, the p75 NGFR messenger RNA (mRNA) content increased after birth and remained elevated at the time of follicular assembly. The NGF and trkA genes showed a different pattern of expression, as the ovarian content of both NGF and trkA mRNA decreased at the time of folliculogenesis. In contrast to the drop in NGF and trkA mRNA expression, NT-4 mRNA levels increased at the time of follicular assembly, coinciding with the abrupt appearance of trkB mRNA. In situ hybridization showed that the increase in NT-4 mRNA expression occurred in a subpopulation of oocytes between 24-48 h after birth, and that the trkB gene became predominantly expressed at this time in epithelial pregranulosa cells. Substantial, but unchanging, levels of NT-3 mRNA and the mRNA encoding trkC, the preferred NT-3 receptor, were detected throughout the perinatal period examined. Very low and invariable levels of BDNF were also detected.(ABSTRACT TRUNCATED AT 400 WORDS)
越来越多的证据表明,神经营养因子不仅能促进神经元的存活和分化,还能作用于非神经元细胞。神经营养因子通过与trk原癌基因家族的细胞膜酪氨酸激酶受体结合来启动其生物学效应。此外,所有神经营养因子都以相似的亲和力识别另一种受体分子,即p75神经生长因子受体(p75 NGFR)或低亲和力NGFR,它似乎与trk受体相互作用,增强它们对神经营养因子的反应。已证明成熟的哺乳动物卵巢能合成几种神经营养因子,包括神经生长因子(NGF)、神经营养因子3(NT-3)和神经营养因子4/5(NT-4/5)。卵巢还表达一些神经营养因子受体,包括p75 NGFR、trkB[NT-4/5和脑源性神经营养因子(BDNF)受体]和trkA(NGF受体)。本实验旨在确定神经营养因子及其受体在卵巢最终组织发生时是否表达,以及它们是否表现出与卵泡发生完成相关的发育表达模式。对大鼠胚胎卵巢中p75 NGFR的免疫组织化学鉴定显示,该受体主要表达于间充质细胞。到妊娠第18天,这些细胞形成腔隙,将假定的前颗粒细胞和卵母细胞群包围成产卵索。出生后立即,产卵索被细分,导致出生后24至48小时之间突然形成原始卵泡。与这些观察结果一致,出生后p75 NGFR信使核糖核酸(mRNA)含量增加,并在卵泡组装时保持升高。NGF和trkA基因表现出不同的表达模式,因为在卵泡发生时,NGF和trkA mRNA的卵巢含量均下降。与NGF和trkA mRNA表达下降相反,NT-4 mRNA水平在卵泡组装时增加,与trkB mRNA的突然出现同时发生。原位杂交显示,NT-4 mRNA表达的增加发生在出生后24至48小时之间的一部分卵母细胞中,并且trkB基因此时主要在上皮前颗粒细胞中表达。在整个围产期检测到NT-3 mRNA和编码trkC(NT-3的首选受体)的mRNA水平较高但无变化。还检测到极低且恒定水平的BDNF。(摘要截断于400字)
