van den Pol A N
Section of Neurosurgery, Yale University School of Medicine, New Haven, Connecticut 06510.
J Neurosci. 1991 Jul;11(7):2087-101. doi: 10.1523/JNEUROSCI.11-07-02087.1991.
Within the hypothalamus, a large number of neuroactive substances are found, many first detected in this part of the brain. Excitatory amino acids, recognized as important transmitters in other parts of the brain, have received little attention here. To study glutamate immunoreactivity at the ultrastructural level in the hypothalamus, postembedding colloidal gold or silver-intensified gold was used. Antisera raised against glutamate conjugated with glutaraldehyde to keyhole limpet hemocyanin were specific for glutamate, tested with a battery of tests including immunodot blot, ELISA assays. Western blot, and Sepharose epoxy-conjugated amino acids. Antisera did not cross-react with other amino acids and related compounds, with proteins containing glutamate, or with polyglutamate. A population of presynaptic boutons in the suprachiasmatic, arcuate, ventromedial, supraoptic, and parvocellular and magnocellular paraventricular nuclei showed strong immunoreactivity for glutamate. Highly labeled presynaptic axons generally made asymmetrical Gray type 1 synaptic contacts with dendrites or cell bodies and had up to eight times more immunogold particles per unit area than postsynaptic dendrites. Axon terminals exhibiting strong glutamate immunoreactivity had large numbers of round, clear vesicles adjacent to the synaptic specialization together with a few larger, dense-core vesicles. The largest number of gold particles over axons were located in regions containing the small clear vesicles. Axons in general had about three times more gold particles over them than did the postsynaptic dendrites. Staining of single boutons in adjacent serial ultrathin sections with glutamate or GABA antisera showed that non-GABAergic terminals had a higher level of glutamate staining than did axons immunoreactive for GABA. In control experiments, immunostaining with glutamate antiserum could be blocked by solid-phase absorption of the antiserum with glutamate conjugated with glutaraldehyde to proteins. Aspartate was also detected with immunocytochemistry in some presynaptic boutons in the medial hypothalamus. To compare the response of neurons to aspartate and glutamate, calcium-imaging dyes were used in combination with digital video microscopy. Whereas almost all neurons showed a rise in intracellular Ca2+ in response to glutamate, many but not all of the same cells also showed a Ca2+ rise of smaller magnitude in response to aspartate. These ultrastructural immunocytochemical data, taken in conjunction with biochemical and electrophysiological experiments, suggest that glutamate, and to a lesser extent aspartate, may play an important neurotransmitter role in a wide variety of hypothalamic circuits.
在下丘脑中发现了大量神经活性物质,其中许多最早是在大脑的这一部分被检测到的。兴奋性氨基酸在大脑其他部位被认为是重要的神经递质,但在这里却很少受到关注。为了在超微结构水平上研究下丘脑谷氨酸免疫反应性,采用了包埋后胶体金或银增强金法。用与戊二醛偶联的谷氨酸对钥孔血蓝蛋白制备的抗血清对谷氨酸具有特异性,通过包括免疫斑点印迹、酶联免疫吸附测定、蛋白质印迹和琼脂糖环氧偶联氨基酸等一系列测试进行检测。抗血清不与其他氨基酸及相关化合物、含谷氨酸的蛋白质或多聚谷氨酸发生交叉反应。视交叉上核、弓状核、腹内侧核、视上核以及小细胞和大细胞室旁核中的一群突触前终扣对谷氨酸显示出强烈的免疫反应性。高度标记的突触前轴突通常与树突或细胞体形成不对称的I型Gray突触联系,每单位面积的免疫金颗粒比突触后树突多多达八倍。表现出强烈谷氨酸免疫反应性的轴突终末在突触特化附近有大量圆形、清亮的小泡,以及一些较大的、有致密核心的小泡。轴突上最多的金颗粒位于含有小清亮小泡的区域。一般来说,轴突上的金颗粒比突触后树突多大约三倍。用谷氨酸或γ-氨基丁酸抗血清对相邻连续超薄切片中的单个终扣进行染色,结果显示非γ-氨基丁酸能终末的谷氨酸染色水平高于对γ-氨基丁酸有免疫反应性的轴突。在对照实验中,用与戊二醛偶联的谷氨酸对蛋白质进行固相吸收抗血清,可阻断谷氨酸抗血清的免疫染色。在下丘脑内侧的一些突触前终扣中也通过免疫细胞化学检测到了天冬氨酸。为了比较神经元对天冬氨酸和谷氨酸的反应,将钙成像染料与数字视频显微镜结合使用。几乎所有神经元对谷氨酸都表现出细胞内钙离子浓度升高,而许多但并非所有相同的细胞对天冬氨酸也表现出较小幅度的钙离子浓度升高。这些超微结构免疫细胞化学数据,结合生化和电生理实验,表明谷氨酸,以及程度较轻的天冬氨酸,可能在多种下丘脑回路中发挥重要的神经递质作用。