Spinedi E, Johnston C, Negro-Vilar A
Endocrinology. 1984 Jul;115(1):267-72. doi: 10.1210/endo-115-1-267.
Neonatal treatment with monosodium glutamate (MSG) induces severe neuronal damage in selected brain areas, which in turn results in a number of neuroendocrine abnormalities during adult life. The present study was designed to determine what effects this partial and selective denervation of the hypothalamic-pituitary axis may have on the sensitivity of two key components of that axis, the median eminence (ME) and the anterior pituitary (AP). In order to test any changes in response that may occur after MSG treatment, the release of several peptide hormones from either the ME or the AP was evaluated in vitro, employing specific or general secretagogues. Male newborn pups of the Holtzman strain were injected with MSG every other day for 5 days, starting on day 2 of life; littermate controls received an injection of 10% NaCl. All animals were used when adult, at about 5-7 months of age. After decapitation, ME and AP tissues from control and MSG-treated rats were dissected out and incubated in vitro. Release of LHRH, SRIF, arginine vasopressin, and oxytocin from the ME was measured by direct RIA, under basal conditions and after stimulation with high K+ medium (28 mM). The results clearly indicate a marked hyperresponse of the release of each of the four neuropeptides by ME fragments from MSG-lesioned animals. The altered release was not attributable to changes in ME peptide content. In the case of the AP, the release of ACTH, LH, PRL, and GH in response to high K+ or, in some cases, to specific releasing factors, was evaluated in a dispersed cell preparation. The release of all four protein hormones was increased by high K+, and again the MSG-lesioned rats showed a pronounced hyperresponse. Corticotropin-releasing factor, at concentrations of 10(-9) and 10(-8) M enhanced ACTH release from control and MSG-lesioned rats, but the latter presented a marked hyperresponse. A similar observation on LH release was seen after stimulation with LHRH (10(-9) M). The results indicate that the neuronal damage induced by neonatal MSG treatment results in a generalized hyperresponsiveness in vitro to either specific or general secretagogues by ME or AP tissues, which may suggest the development of a denervation-type supersensitivity in the hypothalamic-pituitary axis. Since the release of these peptide hormones is sluggish in MSG-lesioned rats under in vivo conditions, it seems plausible to conclude that the major defect after the neurotoxin damage may reside in the loss of neurotransmitter systems normally innervating and regulating the activity of the peptidergic neurons.
新生期用谷氨酸钠(MSG)处理会在特定脑区诱导严重的神经元损伤,这进而会在成年期导致多种神经内分泌异常。本研究旨在确定下丘脑 - 垂体轴的这种部分性和选择性去神经支配可能对该轴的两个关键组成部分,即正中隆起(ME)和垂体前叶(AP)的敏感性产生何种影响。为了测试MSG处理后可能发生的反应变化,采用特异性或非特异性促分泌剂在体外评估了ME或AP中几种肽类激素的释放。Holtzman品系的雄性新生幼崽从出生后第2天开始每隔一天注射一次MSG,共注射5天;同窝对照注射10%氯化钠。所有动物在成年时(约5 - 7个月大)用于实验。断头后,解剖出对照和MSG处理大鼠的ME和AP组织并进行体外孵育。在基础条件下以及用高钾培养基(28 mM)刺激后,通过直接放射免疫分析法(RIA)测量ME中促性腺激素释放激素(LHRH)、生长抑素(SRIF)、精氨酸加压素和催产素的释放。结果清楚地表明,来自MSG损伤动物的ME片段对四种神经肽中每一种的释放均有明显的高反应性。释放的改变并非归因于ME肽含量的变化。对于AP,在分散细胞制备物中评估了促肾上腺皮质激素(ACTH)、促黄体生成素(LH)、催乳素(PRL)和生长激素(GH)对高钾或在某些情况下对特异性释放因子的反应释放。高钾增加了所有四种蛋白质激素的释放,并且MSG损伤的大鼠再次表现出明显的高反应性。促肾上腺皮质激素释放因子在浓度为10^(-9)和10^(-8) M时增强了对照和MSG损伤大鼠的ACTH释放,但后者表现出明显的高反应性。在用促性腺激素释放激素(10^(-9) M)刺激后,对LH释放也有类似的观察结果。结果表明,新生期MSG处理诱导的神经元损伤导致ME或AP组织在体外对特异性或非特异性促分泌剂普遍出现高反应性,这可能提示下丘脑 - 垂体轴中出现了去神经支配型超敏反应。由于在体内条件下,MSG损伤大鼠中这些肽类激素的释放缓慢,似乎可以合理地得出结论,神经毒素损伤后的主要缺陷可能在于正常支配和调节肽能神经元活性的神经递质系统的丧失。
