Maidment N T, Siddall B J, Rudolph V R, Erdelyi E, Evans C J
Department of Psychiatry and Biobehavioral Sciences, U.C.L.A. School of Medicine 90024.
Neuroscience. 1991;45(1):81-93. doi: 10.1016/0306-4522(91)90105-w.
Microdialysis was combined with a highly sensitive sequential multiple antigen radioimmunoassay to simultaneously measure extracellular cholecystokinin and neurotensin fragments from discrete regions of the rat brain in vivo. The assay was conducted in 96-well plates and provided a limit of detection for both peptides of 0.1 fmol. Dialysis membranes composed of polyacrylonitrile, Cuprophan and polycarbonate were evaluated in vitro using both radiolabelled peptides and radioimmunoassay. Polycarbonate probes were implanted in the posterior medial nucleus accumbens-septum, medial caudate nucleus or medial prefrontal cortex of halothane-N2O-anaesthetized rats. Cholecystokinin immunoreactivity levels were generally above the assay detection limits (0.1-0.7 fmol) in 30-min samples from all three regions under basal conditions. Recovered basal amounts of neurotensin immunoreactivity were detectable in the nucleus accumbens-septum in approximately 50% of experiments (0.1-0.2 fmol) but were not measured in the caudate nucleus or prefrontal cortex. In the nucleus accumbens-septum, a 10-min pulse of 200 mM K(+)-containing artificial cerebrospinal fluid in the perfusion medium during a 30-min sampling period increased the recovered cholecystokinin and neurotensin immunoreactivity to 9.7 fmol +/- 1.9 S.E.M. and 5.8 +/- 1.6 S.E.M., respectively. A second stimulation following a 2.5-h interval produced similar elevations with S2:S1 ratios of 0.62 +/- 0.07 and 0.68 +/- 0.07 for cholecystokinin and neurotensin, respectively. In a separate series of experiments the second stimulation of both peptides was prevented by perfusion of a 10 mM EGTA-containing medium. Similar results were obtained in the caudate nucleus for cholecystokinin, but K(+)-induced elevations in neurotensin immunoreactivity were much smaller (0.5 fmol) in this brain region and calcium dependency was not established. Sequential K+ stimulations at 50, 100 and 200 mM produced progressively greater increases in recovered cholecystokinin and neurotensin immunoreactivity from the nucleus accumbens-septum and of cholecystokinin immunoreactivity from the prefrontal cortex. No neurotensin immunoreactivity was detected in the prefrontal cortex following K+ stimulation. Large post mortem increases in the recovered amounts of cholecystokinin and neurotensin immunoreactivity were observed. This effect was significantly attenuated by EGTA although there was a large calcium-independent component of the cholecystokinin immunoreactivity. On reverse-phase high-performance liquid chromatography the major cholecystokinin-immunoreactive peak co-eluted with sulphated cholecystokinin octapeptide. Neurotensin-immunoreactive material co-eluted with neurotensin (1-13), neurotensin (1-12), neurotensin (1-11), neurotensin (1-10) and neurotensin (1-8). These results further demonstrate the potential of microdialysis for studying neuropeptide release and metabolism in vivo when combined with sufficiently sensitive assay procedures.
微透析技术与高灵敏度的序列多重抗原放射免疫测定法相结合,用于在体同时测量大鼠脑离散区域细胞外的胆囊收缩素和神经降压素片段。该测定在96孔板中进行,两种肽的检测限均为0.1飞摩尔。使用放射性标记肽和放射免疫测定法在体外评估了由聚丙烯腈、铜氨纤维和聚碳酸酯组成的透析膜。将聚碳酸酯探针植入氟烷 - N₂O麻醉大鼠的伏隔核 - 隔区后内侧核、尾状核内侧或前额叶内侧皮质。在基础条件下,来自所有三个区域的30分钟样本中,胆囊收缩素免疫反应性水平通常高于测定检测限(0.1 - 0.7飞摩尔)。在大约50%的实验中,伏隔核 - 隔区可检测到基础量的神经降压素免疫反应性(0.1 - 0.2飞摩尔),但在尾状核或前额叶皮质中未检测到。在伏隔核 - 隔区,在30分钟采样期内,灌注介质中含200 mM K⁺的人工脑脊液10分钟脉冲使回收的胆囊收缩素和神经降压素免疫反应性分别增加到9.7飞摩尔±1.9标准误和5.8±1.6标准误。间隔2.5小时后的第二次刺激产生了类似的升高,胆囊收缩素和神经降压素的S2:S1比值分别为0.62±0.07和0.68±0.07。在另一系列实验中,灌注含10 mM EGTA的介质可阻止两种肽的第二次刺激。在尾状核中,胆囊收缩素得到了类似结果,但该脑区K⁺诱导的神经降压素免疫反应性升高要小得多(0.5飞摩尔),且未确定其钙依赖性。50、100和200 mM的连续K⁺刺激使伏隔核 - 隔区回收的胆囊收缩素和神经降压素免疫反应性以及前额叶皮质的胆囊收缩素免疫反应性逐渐增加。K⁺刺激后,前额叶皮质未检测到神经降压素免疫反应性。死后回收的胆囊收缩素和神经降压素免疫反应性大幅增加。尽管胆囊收缩素免疫反应性有很大一部分是钙非依赖性的,但EGTA可显著减弱这种效应。在反相高效液相色谱上,主要的胆囊收缩素免疫反应性峰与硫酸化胆囊收缩素八肽共洗脱。神经降压素免疫反应性物质与神经降压素(1 - 13)、神经降压素(1 - 12)、神经降压素(1 - 11)、神经降压素(1 - 10)和神经降压素(1 - 8)共洗脱。这些结果进一步证明了微透析技术与足够灵敏的测定方法相结合用于研究体内神经肽释放和代谢的潜力。
