Pau K Y, Lee C J, Cowles A, Yang S P, Hess D L, Spies H G
Division of Reproductive Sciences, Oregon Regional Primate Research Center, Beaverton 97006, USA.
J Neuroendocrinol. 1998 Jan;10(1):21-9. doi: 10.1046/j.1365-2826.1998.00173.x.
Pulsatile secretion of hypothalamic gonadotropin-releasing hormone (GnRH) is suppressed by alpha-adrenergic antagonists in ovariectomized (OVX) rabbits, thus suggesting that initiation of GnRH pulses requires the presence of norepinephrine (NE) stimulation. Terminals of NE neurons are located in proximity with GnRH cells in the hypothalamus, including the arcuate nucleus-median eminence (AME) region. Synaptic NE molecules may be catabolized or transported back to NE terminals (i.e. reuptake) via specific NE transporter proteins (NET). Thus, the amount of synaptic NE acting on GnRH cells is a function of the rate of NE release, metabolism and reuptake. Hypothetically, the rise and fall of a GnRH pulse may be associated with the similar fluctuations of synaptic NE release and/or NET activity. To test this hypothesis, we examined the effects of AME administration of desipramine (DMI, a specific NET blocking drug) on GnRH release. First, we delivered 0.2-10 mM doses of DMI continuously for 1 h via an AME microdialysis (microD) system into intact male rabbits. We found that each AME-DMI infusion, between dosages of 1 mM and 10 mM, stimulated a GnRH pulse, and that the size of these GnRH pulses were proportional to the dosage of DMI. To confirm the specificity of DMI on NET, we measured catecholamine content in microD samples by HPLC. The temporal (60 min) DMI induced a pattern of NE release that included a rising limb within the first 20-30 min; although NE returned to baseline values within the period of DMI treatment. Neither epinephrine nor dopamine levels were changed by DMI. Second, a median dose of DMI (5 mM) was given by microD for 60 min in four separate rabbit models: gonadal intact females (F-INT), intact males (M-INT), gonadectomized females (F-GDX) and castrated males (M-GDX). Individual microD samples were measured for NE and GnRH. Regardless of gender or gonadal status, 5 mM of DMI concomitantly induced a pulse-like release of NE and GnRH. Furthermore, the response of GnRH to DMI was greater in GDX rabbits than in INT animals of both genders. Third, we administered DMI (5 mM) for 30 min via a push-pull perfusion (PPP) system during four repeated 90 min intervals, in either F-INT or ovariectomized (F-GDX) females, and measured GnRH in PPP samples. In both F-INT and F-GDX, each DMI challenge induced a GnRH pulse. In F-INT, all sequential DMI-induced GnRH pulses were nearly equal in size. In contrast, in F-GDX, the first DMI-induced GnRH pulse was greater than subsequent ones. Collectively, these observations are consistent with the concept of noradrenergic regulation of pulsatile GnRH release, and we conclude that the temporal activity of NET may be an integral part of the mechanism by which GnRH pulses operate.
在去卵巢(OVX)兔中,α-肾上腺素能拮抗剂可抑制下丘脑促性腺激素释放激素(GnRH)的脉冲式分泌,这表明GnRH脉冲的起始需要去甲肾上腺素(NE)刺激的存在。NE神经元的终末位于下丘脑GnRH细胞附近,包括弓状核-正中隆起(AME)区域。突触NE分子可通过特定的NE转运蛋白(NET)进行分解代谢或转运回NE终末(即再摄取)。因此,作用于GnRH细胞的突触NE量是NE释放、代谢和再摄取速率的函数。假设GnRH脉冲的上升和下降可能与突触NE释放和/或NET活性的类似波动有关。为了验证这一假设,我们研究了通过AME给予地昔帕明(DMI,一种特异性NET阻断药物)对GnRH释放的影响。首先,我们通过AME微透析(microD)系统将0.2-10 mM剂量的DMI连续1小时注入完整雄性兔体内。我们发现,在1 mM至10 mM剂量之间的每次AME-DMI输注都会刺激一个GnRH脉冲,并且这些GnRH脉冲的大小与DMI剂量成正比。为了确认DMI对NET的特异性,我们通过高效液相色谱法测量了microD样品中的儿茶酚胺含量。在60分钟的时间内,DMI诱导了一种NE释放模式,其中包括在最初20-30分钟内的上升阶段;尽管在DMI治疗期间NE恢复到基线值。DMI对肾上腺素和多巴胺水平均无影响。其次,在四个不同的兔模型中,通过microD给予中剂量的DMI(5 mM)60分钟:性腺完整的雌性(F-INT)、完整雄性(M-INT)、去性腺雌性(F-GDX)和去势雄性(M-GDX)。对各个microD样品进行NE和GnRH测量。无论性别或性腺状态如何,5 mM的DMI均会同时诱导NE和GnRH的脉冲样释放。此外,GDX兔中GnRH对DMI的反应比两性的INT动物更大。第三,我们在F-INT或去卵巢(F-GDX)雌性动物中,通过推挽灌注(PPP)系统在四个重复的90分钟间隔内每次给予DMI(5 mM)30分钟,并测量PPP样品中的GnRH。在F-INT和F-GDX中,每次DMI刺激均诱导一个GnRH脉冲。在F-INT中,所有连续的DMI诱导的GnRH脉冲大小几乎相等。相比之下,在F-GDX中,第一个DMI诱导的GnRH脉冲大于后续脉冲。总体而言,这些观察结果与去甲肾上腺素能调节脉冲式GnRH释放的概念一致,并且我们得出结论,NET的时间活性可能是GnRH脉冲运作机制的一个组成部分。
