Institute of Neuro- and Sensory Physiology, University Medical Center Göttingen, 37073 Göttingen, Germany.
Faculty of Physics and Center for Nanoscience, LMU Munich, 80539, Munich, Germany and Max Planck Institute of Biochemistry, 82152, Martinsried, Germany.
Nanoscale. 2020 May 14;12(18):10226-10239. doi: 10.1039/d0nr00227e.
A standard procedure to study cellular elements is via immunostaining followed by optical imaging. This methodology typically requires target-specific primary antibodies (1.Abs), which are revealed by secondary antibodies (2.Abs). Unfortunately, the antibody bivalency, polyclonality, and large size can result in a series of artifacts. Alternatively, small, monovalent probes, such as single-domain antibodies (nanobodies) have been suggested to minimize these limitations. The discovery and validation of nanobodies against specific targets are challenging, thus only a minimal amount of them are currently available. Here, we used STED, DNA-PAINT, and light-sheet microscopy, to demonstrate that secondary nanobodies (1) increase localization accuracy compared to 2.Abs; (2) allow direct pre-mixing with 1.Abs before staining, reducing experimental time, and enabling the use of multiple 1.Abs from the same species; (3) penetrate thick tissues more efficiently; and (4) avoid probe-induced clustering of target molecules observed with conventional 2.Abs in living or poorly fixed samples. Altogether, we show how secondary nanobodies are a valuable alternative to 2.Abs.
研究细胞成分的标准程序是通过免疫染色,然后进行光学成像。这种方法通常需要针对特定目标的抗体(1.Abs),这些抗体通过二级抗体(2.Abs)来揭示。不幸的是,抗体的二价性、多克隆性和大尺寸会导致一系列的假象。相反,小的、单价的探针,如单域抗体(纳米抗体)已被建议用来最大限度地减少这些限制。针对特定目标的纳米抗体的发现和验证具有挑战性,因此目前只有少量的纳米抗体可用。在这里,我们使用 STED、DNA-PAINT 和光片显微镜,证明了二级纳米抗体(1)与 2.Abs 相比,提高了定位精度;(2)允许在染色前直接与 1.Abs 预混合,从而减少了实验时间,并能够从同一物种使用多个 1.Abs;(3)更有效地穿透厚组织;(4)避免了在活的或固定不良的样本中用传统的 2.Abs 观察到的目标分子的探针诱导聚集。总的来说,我们展示了二级纳米抗体如何成为 2.Abs 的一种有价值的替代品。
