Imaging Centre, IGBMC (Institut de Génétique et de Biologie Moléculaire et Cellulaire), Illkirch, France.
PLoS One. 2010 Feb 3;5(2):e9014. doi: 10.1371/journal.pone.0009014.
In cell biology, the study of proteins and organelles requires the combination of different imaging approaches, from live recordings with light microscopy (LM) to electron microscopy (EM).
To correlate dynamic events in adherent cells with both ultrastructural and 3D information, we developed a method for cultured cells that combines confocal time-lapse images of GFP-tagged proteins with electron microscopy. With laser micro-patterned culture substrate, we created coordinates that were conserved at every step of the sample preparation and visualization processes. Specifically designed for cryo-fixation, this method allowed a fast freezing of dynamic events within seconds and their ultrastructural characterization. We provide examples of the dynamic oligomerization of GFP-tagged myotubularin (MTM1) phosphoinositides phosphatase induced by osmotic stress, and of the ultrastructure of membrane tubules dependent on amphiphysin 2 (BIN1) expression.
Accessible and versatile, we show that this approach is efficient to routinely correlate functional and dynamic LM with high resolution morphology by EM, with immuno-EM labeling, with 3D reconstruction using serial immuno-EM or tomography, and with scanning-EM.
在细胞生物学中,蛋白质和细胞器的研究需要结合不同的成像方法,从使用荧光显微镜(LM)的活细胞记录到电子显微镜(EM)。
为了将贴壁细胞中的动态事件与超微结构和 3D 信息相关联,我们开发了一种针对培养细胞的方法,该方法将 GFP 标记蛋白的共聚焦时程图像与电子显微镜相结合。通过激光微图案化培养基质,我们创建了在样品制备和可视化过程的每一步都保持一致的坐标。该方法专门设计用于冷冻固定,可以在几秒钟内快速冻结动态事件,并对其进行超微结构表征。我们提供了 GFP 标记的肌小管素(MTM1)磷酸脂酶受渗透压胁迫诱导的 GFP 标记的肌小管素(MTM1)磷酸脂酶动态寡聚化的例子,以及依赖于 amphiphysin 2(BIN1)表达的膜小管的超微结构。
这种方法易于使用且功能多样,我们证明它可以有效地将功能和动态 LM 与 EM 的高分辨率形态学、免疫 EM 标记、使用免疫 EM 或断层扫描的 3D 重建以及扫描 EM 常规相关联。