Department of Pharmaceutical Sciences, University of California Irvine, Irvine, California 92697, USA.
J Comp Neurol. 2011 Jul 1;519(10):1847-66. doi: 10.1002/cne.22603.
Neuropeptide S (NPS) has been associated with a number of complex brain functions, including anxiety-like behaviors, arousal, sleep-wakefulness regulation, drug-seeking behaviors, and learning and memory. In order to better understand how NPS influences these functions in a neuronal network context, it is critical to identify transmitter systems that control NPS release and transmitters that are co-released with NPS. For this purpose, we generated several lines of transgenic mice that express enhanced green-fluorescent protein (EGFP) under control of the endogenous NPS precursor promoter. NPS/EGFP-transgenic mice show anatomically correct and overlapping expression of both NPS and EGFP. A total number of ∼500 NPS/EGFP-positive neurons are present in the mouse brain, located in the pericoerulear region and the Kölliker-Fuse nucleus. NPS and transgene expression is first detectable around E14, indicating a potential role for NPS in brain development. EGFP-positive cells were harvested by laser-capture microdissection, and mRNA was extracted for expression profiling by using microarray analysis. NPS was found co-localized with galanin in the Kölliker-Fuse nucleus of the lateral parabrachial area. A dense network of orexin/hypocretin neuronal projections contacting pericoerulear NPS-producing neurons was observed by immunostaining. Expression of a distinct repertoire of metabotropic and ionotropic receptor genes was identified in both NPS neuronal clusters that will allow for detailed investigations of incoming neurotransmission, controlling neuronal activity of NPS-producing neurons. Stress-induced functional activation of NPS-producing neurons was detected by staining for the immediate-early gene c-fos, thus supporting earlier findings that NPS might be part of the brain stress response network.
神经肽 S(NPS)与许多复杂的大脑功能有关,包括类似焦虑的行为、觉醒、睡眠-觉醒调节、觅药行为以及学习和记忆。为了更好地了解 NPS 在神经元网络背景下如何影响这些功能,识别控制 NPS 释放的递质系统以及与 NPS 共同释放的递质系统至关重要。为此,我们生成了几行表达增强型绿色荧光蛋白(EGFP)的转基因小鼠,该蛋白受内源性 NPS 前体启动子的控制。NPS/EGFP 转基因小鼠表现出 NPS 和 EGFP 的解剖学上正确且重叠的表达。在小鼠脑中存在约 500 个 NPS/EGFP 阳性神经元,位于peri-coerulear 区和 Kölliker-Fuse 核。NPS 和转基因表达最早可在 E14 左右检测到,表明 NPS 在大脑发育中具有潜在作用。通过激光捕获显微切割收集 EGFP 阳性细胞,并通过微阵列分析提取 mRNA 进行表达谱分析。发现 NPS 在外侧臂旁区 Kölliker-Fuse 核中与甘丙肽共定位。通过免疫染色观察到与peri-coerulear NPS 产生神经元接触的orexin/hypocretin 神经元投射的密集网络。在两个 NPS 神经元簇中鉴定出了独特的代谢型和离子型受体基因表达谱,这将允许对传入神经传递进行详细研究,控制 NPS 产生神经元的神经元活动。通过对即刻早期基因 c-fos 的染色检测到 NPS 产生神经元的应激诱导功能激活,从而支持了 NPS 可能是大脑应激反应网络的一部分的早期发现。
