红移电压敏感荧光蛋白
Red-shifted voltage-sensitive fluorescent proteins.
作者信息
Perron Amelie, Mutoh Hiroki, Launey Thomas, Knöpfel Thomas
机构信息
Laboratory for Neuronal Circuit Dynamics, RIKEN Brain Science Institute, Wako-shi, Saitama 351-0198, Japan.
出版信息
Chem Biol. 2009 Dec 24;16(12):1268-77. doi: 10.1016/j.chembiol.2009.11.014.
Abstract
Electrical signals generated by nerve cells provide the basis of brain function. Whereas single or small numbers of cells are easily accessible using microelectrode recording techniques, less invasive optogenetic methods with spectral properties optimized for in vivo imaging are required for elucidating the operation mechanisms of neuronal circuits composed of large numbers of neurons originating from heterogeneous populations. To this end, we generated and characterized a series of genetically encoded voltage-sensitive fluorescent proteins by molecular fusion of the voltage-sensing domain of Ci-VSP (Ciona intestinalis voltage sensor-containing phosphatase) to red-shifted fluorescent protein operands. We show how these indicator proteins convert voltage-dependent structural rearrangements into a modulation of fluorescence output and demonstrate their applicability for optical recording of individual or simultaneous electrical signals in cultured hippocampal neurons at single-cell resolution without temporal averaging.
摘要
神经细胞产生的电信号是脑功能的基础。虽然使用微电极记录技术能够轻松获取单个或少量细胞的信号,但要阐明由异质群体中大量神经元组成的神经回路的运作机制,就需要采用侵入性较小且光谱特性针对体内成像进行了优化的光遗传学方法。为此,我们通过将Ci-VSP(海鞘电压传感磷酸酶)的电压传感结构域与红移荧光蛋白操作子进行分子融合,生成并表征了一系列基因编码的电压敏感荧光蛋白。我们展示了这些指示蛋白如何将电压依赖性结构重排转化为荧光输出的调制,并证明了它们在单细胞分辨率下对培养的海马神经元中单个或同时发生的电信号进行光学记录的适用性,且无需时间平均。
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