Nanoscale imaging of RNA with expansion microscopy.
PMID:27376770
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IF: 47.990
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Cited by: 280
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Abstract

The ability to image RNA identity and location with nanoscale precision in intact tissues is of great interest for defining cell types and states in normal and pathological biological settings. Here, we present a strategy for expansion microscopy of RNA. We developed a small-molecule linker that enables RNA to be covalently attached to a swellable polyelectrolyte gel synthesized throughout a biological specimen. Then, postexpansion, fluorescent in situ hybridization (FISH) imaging of RNA can be performed with high yield and specificity as well as single-molecule precision in both cultured cells and intact brain tissue. Expansion FISH (ExFISH) separates RNAs and supports amplification of single-molecule signals (i.e., via hybridization chain reaction) as well as multiplexed RNA FISH readout. ExFISH thus enables super-resolution imaging of RNA structure and location with diffraction-limited microscopes in thick specimens, such as intact brain tissue and other tissues of importance to biology and medicine.

Keywords

ExFISH

MeSH terms

Acrylamides
Animals
Brain
Cells, Cultured
HeLa Cells
Humans
Image Processing, Computer-Assisted
In Situ Hybridization, Fluorescence
Mice
Microscopy, Fluorescence
Nanotechnology
Oligonucleotide Probes
Optical Imaging
RNA

Authors

Chen, Fei
Wassie, Asmamaw T
Cote, Allison J
Sinha, Anubhav
Alon, Shahar
Asano, Shoh
Daugharthy, Evan R
Chang, Jae-Byum
Marblestone, Adam
Church, George M
Raj, Arjun
Boyden, Edward S

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