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Engineered fast-dissociating antibody fragments for multiplexed super-resolution microscopy

Qianli Zhang, Akitoshi Miyamoto, Shin Watanabe, Takao Arimori, Masanori Sakai, Madoka Tomisaki, Tai Kiuchi, Junichi Takagi, Naoki Watanabe

2022Cell Reports Methods13 citationsDOIOpen Access PDF

Abstract

Image reconstruction by integrating exchangeable single-molecule localization (IRIS) achieves multiplexed super-resolution imaging by high-density labeling with fast exchangeable fluorescent probes. However, previous methods to develop probes for individual targets required a great amount of time and effort. Here, we introduce a method for generating recombinant IRIS probes with a new mutagenesis strategy that can be widely applied to existing antibody sequences. Several conserved tyrosine residues at the base of complementarity-determining regions were identified as candidate sites for site-directed mutagenesis. With a high probability, mutations at candidate sites accelerated the off rate of recombinant antibody-based probes without compromising specific binding. We were able to develop IRIS probes from five monoclonal antibodies and three single-domain antibodies. We demonstrate multiplexed localization of endogenous proteins in primary neurons that visualizes small synaptic connections with high binding density. It is now practically feasible to generate fast-dissociating fluorescent probes for multitarget super-resolution imaging.

Topics & Concepts

Recombinant DNAMutagenesisMultiplexingComputational biologyMonoclonal antibodyComplementarity determining regionFluorescenceChemistryBiophysicsBiologyAntibodyComputer scienceMutationOpticsGeneticsPhysicsGeneTelecommunicationsAdvanced Fluorescence Microscopy TechniquesAdvanced Electron Microscopy Techniques and ApplicationsCell Image Analysis Techniques
Engineered fast-dissociating antibody fragments for multiplexed super-resolution microscopy | Litcius