Savelyev Sergey A, Larsson Karin C, Johansson Anne-Sofie, Lundkvist Gabriella B S
Swedish Medical Nanoscience Center, Department of Neuroscience, Karolinska Institutet.
J Vis Exp. 2011 Feb 15(48):2439. doi: 10.3791/2439.
A central circadian (~24 hr) clock coordinating daily rhythms in physiology and behavior resides in the suprachiasmatic nucleus (SCN) located in the anterior hypothalamus. The clock is directly synchronized by light via the retina and optic nerve. Circadian oscillations are generated by interacting negative feedback loops of a number of so called "clock genes" and their protein products, including the Period (Per) genes. The core clock is also dependent on membrane depolarization, calcium and cAMP. The SCN shows daily oscillations in clock gene expression, metabolic activity and spontaneous electrical activity. Remarkably, this endogenous cyclic activity persists in adult tissue slices of the SCN. In this way, the biological clock can easily be studied in vitro, allowing molecular, electrophysiological and metabolic investigations of the pacemaker function. The SCN is a small, well-defined bilateral structure located right above the optic chiasm. In the rat it contains ~8.000 neurons in each nucleus and has dimensions of approximately 947 μm (length, rostrocaudal axis) x 424 μm (width) x 390 μm (height). To dissect out the SCN it is necessary to cut a brain slice at the specific level of the brain where the SCN can be identified. Here, we describe the dissecting and slicing procedure of the SCN, which is similar for mouse and rat brains. Further, we show how to culture the dissected tissue organotypically on a membrane, a technique developed for SCN tissue culture by Yamazaki et al. Finally, we demonstrate how transgenic tissue can be used for measuring expression of clock genes/proteins using dynamic luciferase reporter technology, a method that originally was used for circadian measurements by Geusz et al. We here use SCN tissues from the transgenic knock-in PERIOD2::LUCIFERASE mice produced by Yoo et al. The mice contain a fusion protein of PERIOD (PER) 2 and the firefly enzyme LUCIFERASE. When PER2 is translated in the presence of the substrate for luciferase, i.e. luciferin, the PER2 expression can be monitored as bioluminescence when luciferase catalyzes the oxidation of luciferin. The number of emitted photons positively correlates to the amount of produced PER2 protein, and the bioluminescence rhythms match the PER2 protein rhythm in vivo. In this way the cyclic variation in PER2 expression can be continuously monitored real time during many days. The protocol we follow for tissue culturing and real-time bioluminescence recording has been thoroughly described by Yamazaki and Takahashi.
一个协调生理和行为中每日节律的中枢昼夜节律(约24小时)时钟位于下丘脑前部的视交叉上核(SCN)中。该时钟通过视网膜和视神经直接与光同步。昼夜节律振荡是由许多所谓的“时钟基因”及其蛋白质产物相互作用的负反馈回路产生的,包括周期(Per)基因。核心时钟还依赖于膜去极化、钙和环磷酸腺苷。SCN在时钟基因表达、代谢活动和自发电活动方面表现出每日振荡。值得注意的是,这种内源性循环活动在SCN的成年组织切片中持续存在。通过这种方式,可以很容易地在体外研究生物钟,从而对起搏器功能进行分子、电生理和代谢研究。SCN是一个小的、界限分明的双侧结构,位于视交叉正上方。在大鼠中,每个核包含约8000个神经元,尺寸约为947μm(长度, rostrocaudal轴)×424μm(宽度)×390μm(高度)。为了分离出SCN,有必要在大脑中可以识别SCN的特定水平处切取脑片。在这里,我们描述了SCN的分离和切片过程,这在小鼠和大鼠大脑中是相似的。此外,我们展示了如何在膜上对分离的组织进行器官型培养,这是Yamazaki等人开发的用于SCN组织培养的技术。最后,我们展示了如何使用动态荧光素酶报告技术将转基因组织用于测量时钟基因/蛋白质的表达,该方法最初由Geusz等人用于昼夜节律测量。我们在这里使用Yoo等人生产的转基因敲入PERIOD2::LUCIFERASE小鼠的SCN组织。这些小鼠含有周期(PER)2与萤火虫酶荧光素酶的融合蛋白。当PER2在荧光素酶底物即荧光素存在的情况下被翻译时,当荧光素酶催化荧光素氧化时,PER2的表达可以作为生物发光进行监测。发射的光子数量与产生的PER2蛋白量呈正相关,并且生物发光节律与体内的PER2蛋白节律相匹配。通过这种方式,可以在许多天内实时连续监测PER2表达的周期性变化。我们遵循的组织培养和实时生物发光记录方案已由Yamazaki和Takahashi进行了详细描述。
