Bacterially Derived Antibody Binders as Small Adapters for DNA‐PAINT Microscopy

Schlichthaerle, Thomas; Ganji, Mahipal; Auer, Alexander; Wade, Orsolya K.; Jungmann, Ralf

doi:10.1002/cbic.201800743

Cited by 26 publications

(25 citation statements)

References 38 publications

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“…On the other hand, a large amount of well validated monoclonal antibodies is available. Our data suggests that the localization of primary antibodies with recombinant secondary nanobodies or probably other small monovalent binder such as protein A, 33 can minimize the probe-induced clustering of targets, increase the localization accuracy in super-resolution microscopy, lower steric hindrance for detecting more target molecules, enhance the sample penetration, remove the species-limitation by pre-mixing allowing high multiplexing capabilities, and finally, increase the reproducibility of results with no needs of animals.…”

Section: Resultsmentioning

confidence: 88%

Circumvention of common labelling artefacts using secondary nanobodies

et al. 2020

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Section: Resultsmentioning

confidence: 88%

Circumvention of common labelling artefacts using secondary nanobodies

et al. 2020

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“…Recently, Jungmann and co-workers reported similar results when using ODN-functionalized protein A and G variants as secondary, non-covalent, labeling reagents in DNA-PAINT. 32 Since pG-ODN is covalently coupled to the antibody using UV light, we additionally investigated if the pG-ODN antibody coupling is reversed when the construct is exposed to high laser intensity. To validate the stability of the pG-ODN-antibody construct we quantified the number of localizations during image acquisition over the course of 8 minutes (Fig.…”

Section: Resultsmentioning

confidence: 99%

Efficient small-scale conjugation of DNA to primary antibodies for multiplexed cellular targeting

Cremers

Rosier

Brillas

et al. 2019

Preprint

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The combination of the specificity of antibodies and the programmability of DNA nanotechnology has provided the scientific community with a powerful tool to label and unambiguously distinguish a large number of subcellular targets using fluorescence-based read-out methods. While primary antibodies are commercially available for a large class of targets, a general stoichiometric site-specific DNA labeling strategy for this affinity reagent is lacking. Here, we present a universal, site-selective, conjugation method using a small photocrosslinkable protein G adaptor that allows labeling of antibodies of different host species with a controlled number of short oligonucleotides (ODNs). Importantly, we illustrate that this conjugation method can be directly performed on commercially-available primary antibodies, on a small scale and without cross-reactivity towards other proteins, such as bovine serum albumin. In addition, we present a general, benchtopcompatible strategy to purify DNA-labeled antibodies without loss of function. The application of protein G-ODN labeled primary antibodies is demonstrated by employing three well-known methods for detecting subcellular targets using fluorescent read-out, including flow cytometry, DNA-PAINT, and dSTORM. This work thus establishes a general and efficient platform for the synthesis of a library of unique ODN-antibody conjugates, facilitating the broader use of DNA-based programmable tags for multiplexed labeling to identify subcellular features with nanometer-precision, improving our understanding of cellular structure and function.

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“…The transient interaction between the 9-basepair docking strand and imager strand can last up to several hundreds of milliseconds, so blinking is significantly slower than in STORM. Typical exposure times of PAINT images are in the range of 100-500 Ms, with the accumulation of tens of thousands of frames taking up to a few hours for a single image [25,80]. One way to alleviate this is to use FRET-PAINT [81,82] that allows to raise the imager concentration without obtaining an overwhelming background fluorescence.…”

Section: Dna-paintmentioning

confidence: 99%

About samples, giving examples: Optimized Single Molecule Localization Microscopy

Jimenez

Friedl

Leterrier

2020

Methods

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Super-resolution microscopy has profoundly transformed how we study the architecture of cells, revealing unknown structures and refining our view of cellular assemblies. Among the various techniques, the resolution of Single Molecule Localization Microscopy (SMLM) can reach the size of macromolecular complexes and offer key insights on their nanoscale arrangement in situ. SMLM is thus a demanding technique and taking advantage of its full potential requires specifically optimized procedures. Here we describe how we perform the successive steps of an SMLM workflow, focusing on single-color Stochastic Optical Reconstruction Microscopy (STORM) as well as multicolor DNA Points Accumulation for imaging in Nanoscale Topography (DNA-PAINT) of fixed samples. We provide detailed procedures for careful sample fixation and immunostaining of typical cellular structures: cytoskeleton, clathrin-coated pits, and organelles. We then offer guidelines for optimal imaging and processing of SMLM data in order to optimize reconstruction quality and avoid the generation of artifacts. We hope that the tips and tricks we discovered over the years and detail here will be useful for researchers looking to make the best possible SMLM images, a prerequisite for meaningful biological discovery.

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Bacterially Derived Antibody Binders as Small Adapters for DNA‐PAINT Microscopy

Cited by 26 publications

References 38 publications

Circumvention of common labelling artefacts using secondary nanobodies

Circumvention of common labelling artefacts using secondary nanobodies

Efficient small-scale conjugation of DNA to primary antibodies for multiplexed cellular targeting

About samples, giving examples: Optimized Single Molecule Localization Microscopy

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