Department of Physics and Astronomy, Vrije Universiteit (VU University) Amsterdam, Amsterdam, The Netherlands.
Nat Methods. 2013 Sep;10(9):910-6. doi: 10.1038/nmeth.2599. Epub 2013 Aug 11.
Dense coverage of DNA by proteins is a ubiquitous feature of cellular processes such as DNA organization, replication and repair. We present a single-molecule approach capable of visualizing individual DNA-binding proteins on densely covered DNA and in the presence of high protein concentrations. Our approach combines optical tweezers with multicolor confocal and stimulated emission depletion (STED) fluorescence microscopy. Proteins on DNA are visualized at a resolution of 50 nm, a sixfold resolution improvement over that of confocal microscopy. High temporal resolution (<50 ms) is ensured by fast one-dimensional beam scanning. Individual trajectories of proteins translocating on DNA can thus be distinguished and tracked with high precision. We demonstrate our multimodal approach by visualizing the assembly of dense nucleoprotein filaments with unprecedented spatial resolution in real time. Experimental access to the force-dependent kinetics and motility of DNA-associating proteins at biologically relevant protein densities is essential for linking idealized in vitro experiments with the in vivo situation.
蛋白质对 DNA 的密集覆盖是 DNA 组织、复制和修复等细胞过程的普遍特征。我们提出了一种单分子方法,能够在高浓度蛋白质存在的情况下,可视化密集覆盖的 DNA 上的单个 DNA 结合蛋白。我们的方法将光学镊子与多色共聚焦和受激发射损耗(STED)荧光显微镜相结合。在 50nm 的分辨率下可以观察到 DNA 上的蛋白质,比共聚焦显微镜的分辨率提高了六倍。通过快速一维光束扫描,可以确保高时间分辨率(<50ms)。因此,可以区分和高精度跟踪在 DNA 上迁移的蛋白质的单个轨迹。我们通过实时以空前的空间分辨率可视化密集核蛋白丝的组装来证明我们的多模式方法。在生物学相关蛋白质密度下,对与 DNA 相关的蛋白质的力依赖性动力学和迁移性进行实验访问对于将理想化的体外实验与体内情况联系起来至关重要。
