RNA Detection

background fluorescence even when closed, due to imperfect

quenching of the fluorophore by the quencher. Thus, when

delivered into cells, background fluorescence, nonspecific

interactions and cell-to-cell variations in MB delivery can all

lead to misinterpretation of high uptake efficiency for MB

hybridization signals. Ratiometric imaging, a technique that

enables correction for unequal probe delivery, has been a pop-

ular technique for normalizing delivery efficiency in studies

involving the use of fluorescent probes [20]. In the context of

MBs, the technique generally involves comparing the fluores-

cence of the MBs of interest with that of an optically distinct,

nonreactive reference probe both in solution and codelivered

into cells. Comparing the fluorescence ratio of the MBs to the

reference probe in cells with that obtained under well-

controlled conditions provides a means for determining

whether the MB signal in cells reflects MB hybridization or

nonspecific opening. Using this approach, we identified that

MBs with a fully PS-modified loop domain and a phosphodie-

ster stem (2Me/PSLOOPMB) exhibit the lowest false-positive

signal among the six different MB architectures tested in living

cells.

2. 1PBS can also be used as microinjection buffer.


3. ImageJ can also be used for image analysis. Fiji can be down-
   loaded at: http://fiji.sc/. ImageJ can be downloaded at:
   https://imagej.nih.gov/ij/.


4. Dissolve the appropriate quantity of IRDye®800 NHS ester in
   1–5μL anhydrous DMSO or DMF before reacting with the
   aminodextran. Make sure the volume of DMSO or DMF is less
   than 10% of the total reaction mixture.


5. To identify MB backbone architectures that are stable in living
   cells, it is critical to use an appropriate control that enables
   normalization of cell-to-cell variations in delivery. As the back-
   bone stability is unknown, it might not be appropriate to use an
   unquenched beacon as a normalization reference, as both
   quenched and unquenched beacons may be degraded. Alterna-
   tively, we have previously used fluorescently labeled dextran as a
   means for normalizing cellular delivery of molecular beacons
   [18, 19]. The IRDye®800-labeled dextran used in this study
   has a molecular weight (~10 kDa) similar to the MBs, therefore
   the two molecules were expected to exhibit similar transfection
   efficiencies when codelivered into cells by microporation, as
   shown in our previous results [18, 19].


6. Microemulsion bubbles form a range of sizes, and increasing
   the stirring speed can reduce bubble sizes.


7. Experimenters should try to image bubbles that have sizes
   similar to cells.

254 Mingming Chen et al.