小鼠原代肝细胞培养模型的昼夜振荡研究

Q1 Agricultural and Biological Sciences

Current protocols in mouse biology Pub Date : 2015-12-02 DOI:10.1002/9780470942390.mo150101

Penny C. Molyneux, Lorna A. Pyle, Martha Dillon, Mary E. Harrington

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引用次数: 2

摘要

昼夜节律调节行为和生理过程的许多方面，并通过外部信号帮助生物体适应其环境。这些节律是由我们体内许多细胞和组织的生物钟驱动的，并由大脑中的中央起搏器——视交叉上核——同步。外周振荡器包括肝脏，其生物钟控制基因表达和肝脏特异性功能(如代谢稳态和药物代谢)的持续每日节律。长期的生物钟紊乱，如轮班工作，与肥胖、糖尿病和心血管疾病等疾病有关。小鼠原代肝细胞培养模型允许检查这些细胞的昼夜节律。本文描述了一种转基因小鼠模型，该模型使用生物发光报告基因来检测核心时钟基因Period2的昼夜节律特性。使用改良的胶原酶灌注技术分离肝细胞，并在三明治结构中培养，然后将其密封在含有荧光素的缓冲培养基中，以检测全培养或单细胞生物发光。通过培养基变化同步后，培养物显示出来自PERIOD2::LUCIFERASE报告的生物发光的一致的昼夜节律周期和相位测量。©2015 by John Wiley &儿子,Inc。

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A Mouse Primary Hepatocyte Culture Model for Studies of Circadian Oscillation

Circadian rhythms regulate many aspects of behavior and physiological processes, and, through external signals, help an organism entrain to its environment. These rhythms are driven by circadian clocks in many cells and tissues within our bodies, and are synchronized by a central pacemaker in the brain, the suprachiasmatic nucleus. Peripheral oscillators include the liver, whose circadian clock controls persistent daily rhythms in gene expression and in liver-specific functions such as metabolic homeostasis and drug metabolism. Chronic circadian clock disruption, as in rotating shiftwork, has been linked to disorders including obesity, diabetes, and cardiovascular disease. The mouse primary hepatocyte culture model allows the examination of circadian rhythms in these cells. This article describes a transgenic mouse model that uses a bioluminescent reporter to examine the circadian properties of a core clock gene Period2. Hepatocytes are isolated using a modified collagenase perfusion technique and cultured in a sandwich configuration, then sealed in a buffered medium containing luciferin for detection of whole-culture or single-cell bioluminescence. After synchronization by a medium change, cultures demonstrate coherent circadian period and phase measures of bioluminescence from the PERIOD2::LUCIFERASE reporter. © 2015 by John Wiley & Sons, Inc.

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来源期刊

Current protocols in mouse biology Agricultural and Biological Sciences-Animal Science and Zoology

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期刊介绍： Sound and reproducible laboratory methods are the foundation of scientific discovery. Yet, all too often, nuances that are critical for an experiment''s success are not captured in the primary literature but exist only as part of a lab''s oral tradition. The aim of Current Protocols in Mouse Biology is to provide the clearest, most detailed and reliable step-by-step instructions for protocols involving the use of mice in biomedical research. Written by experts in the field and extensively edited to our exacting standards, the protocols include all of the information necessary to complete an experiment in the laboratory—introduction, materials lists with supplier information, detailed step-by-step procedures with helpful annotations, recipes for reagents and solutions, illustrative figures and information-packed tables. Each article also provides invaluable discussions of background information, applications of the methods, important assumptions, key parameters, time considerations, and tips to help avoid common pitfalls and troubleshoot experiments. Furthermore, Current Protocols in Mouse Biology content is thoughtfully organized by topic for optimal usage and to maximize contextual knowledge. Quarterly issues allow Current Protocols to constantly evolve to keep pace with the newest discoveries and developments. Current Protocols in Mouse Biology brings together resources in mouse biology and genetics and provides a mouse protocol resource that covers all aspects of mouse biology. Current Protocols in Mouse Biology also permits optimization of mouse model usage, which is significantly impacted by both cost and ethical constraints. Optimal and standardized mouse protocols ultimately reduce experimental variability and reduce the number of animals used in mouse experiments.