Janelia Farm Research Campus, Howard Hughes Medical Institute, Ashburn, Virginia, USA.
Nat Methods. 2011 Dec 4;9(1):96-102. doi: 10.1038/nmeth.1784.
The GFP reconstitution across synaptic partners (GRASP) technique, based on functional complementation between two nonfluorescent GFP fragments, can be used to detect the location of synapses quickly, accurately and with high spatial resolution. The method has been previously applied in the nematode and the fruit fly but requires substantial modification for use in the mammalian brain. We developed mammalian GRASP (mGRASP) by optimizing transmembrane split-GFP carriers for mammalian synapses. Using in silico protein design, we engineered chimeric synaptic mGRASP fragments that were efficiently delivered to synaptic locations and reconstituted GFP fluorescence in vivo. Furthermore, by integrating molecular and cellular approaches with a computational strategy for the three-dimensional reconstruction of neurons, we applied mGRASP to both long-range circuits and local microcircuits in the mouse hippocampus and thalamocortical regions, analyzing synaptic distribution in single neurons and in dendritic compartments.
GFP 重组跨越突触伙伴(GRASP)技术,基于两个非荧光 GFP 片段之间的功能互补,可用于快速、准确和高空间分辨率地检测突触的位置。该方法以前曾在线虫和果蝇中应用,但需要进行大量修改才能用于哺乳动物大脑。我们通过优化用于哺乳动物突触的跨膜分裂 GFP 载体来开发哺乳动物 GRASP(mGRASP)。我们使用计算机蛋白质设计工程了嵌合突触 mGRASP 片段,这些片段可有效地递送到突触位置,并在体内重新构建 GFP 荧光。此外,通过将分子和细胞方法与用于神经元三维重建的计算策略相结合,我们将 mGRASP 应用于小鼠海马体和丘脑皮层区域的长程回路和局部微回路,分析单个神经元和树突隔室中的突触分布。