attaching a very efficient contact quencher (DN, dinitroaniline) via
a triethylene glycol linker to yield a fluorogenic dye (SR-DN) (see
Fig.3). The fluorescence of SR-DN increases ~100-fold upon
binding to SRB-2 and this dye was utilized to image an RNA of
interest genetically fused to SRB-2 in live bacteria.1.2 RNA Imaging
Using a Quencher-
Binding Aptamer
Even though fluorophore-binding aptamers are invaluable tools for
in vivo RNA imaging, a new aptamer has to be generated for each
fluorophore with a different structure and a different color, which
hampers the multiplexing potential of fluorophore-binding apta-
mers. Therefore, we decided to generate an RNA aptamer that
binds to dinitroaniline, which was previously discovered as a general
and very efficient contact quencher [17, 18]. With this quencher-
binding aptamer, RNA of interests can be easily labeled with differ-
ent colored fluorophores (seeFig. 1b). It is worth mentioning that
quencher-binding aptamers were previously developed; however,
the quenching mechanism of the fluorescent dyes were based on
PeT [19, 20] or FRET [21] quenching. Due to incompleteFig. 2Mfold-predicted secondary structure of (a) SRB-2 aptamer and its binding partner sulforhodamine B
(SR); (b) DNB aptamer and its binding partner dinitroaniline (DN)
Fig. 3Structures of the fluorogenic dyes used in this protocol. Dinitroaniline (DN) and p-nitrobenzylamine (MN)
are the contact quenchers used in this protocol.RG-DNrhodamine green dinitroaniline,TMR-DNtetramethylr-
hodamine dinitroaniline,SR-DNsulforhodamine dinitroaniline,TR-DNTexasRed dinitroaniline,SR-MNsulfor-
hodamine p-nitrobenzylamineVisualizing RNA with Fluorogenic Aptamers in vivo 291