The protocol presents two methods to determine the kinetics of the fluorogenic RNA aptamers Spinach2 and Broccoli. The first method describes how to measure fluorogenic aptamer kinetics in vitro with a plate reader, while the second method details the measurement of fluorogenic aptamer kinetics in cells by flow cytometry.
Fluorogenic RNA aptamers have been applied in live cells to tag and visualize RNAs, report on gene expression, and activate fluorescent biosensors that detect levels of metabolites and signaling molecules. In order to study dynamic changes in each of these systems, it is desirable to obtain real-time measurements, but the accuracy of the measurements depends on the kinetics of the fluorogenic reaction being faster than the sampling frequency. Here, we describe methods to determine the in vitro and cellular turn-on kinetics for fluorogenic RNA aptamers using a plate reader equipped with a sample injector and a flow cytometer, respectively. We show that the in vitro kinetics for the fluorescence activation of the Spinach2 and Broccoli aptamers can be modeled as two-phase association reactions and have differing fast phase rate constants of 0.56 s−1 and 0.35 s−1, respectively. In addition, we show that the cellular kinetics for the fluorescence activation of Spinach2 in Escherichia coli, which is further limited by dye diffusion into the Gram-negative bacteria, is still sufficiently rapid to enable accurate sampling frequency on the minute timescale. These methods to analyze fluorescence activation kinetics are applicable to other fluorogenic RNA aptamers that have been developed.
Fluorogenic reactions are chemical reactions that generate a fluorescence signal. Fluorogenic RNA aptamers typically perform this function by binding a small molecule dye to enhance its fluorescence quantum yield (Figure 1A)1. Different fluorogenic RNA aptamer systems have been developed and consist of specific RNA aptamer sequences and the corresponding dye ligands1. Fluorogenic RNA aptamers have been appended to RNA transcripts as fluorescent tags that enable live cell imaging of mRNAs and non-coding RNAs2,3,4. They have also been placed after promoter sequences as fluorescent reporters of gene expression, similar to the use of green fluorescent protein (GFP) as a reporter, except the reporting function is at the RNA level5,6. Finally, fluorogenic RNA aptamers have been incorporated into RNA-based fluorescent biosensors, which are designed to trigger the fluorogenic reaction in response to a specific small molecule. RNA-based fluorescent biosensors have been developed for live cell imaging of various non-fluorescent metabolites and signaling molecules7,8,9,10,11.
There is growing interest in the development of fluorogenic RNA aptamers to visualize dynamic changes in RNA localization, gene expression, and small molecule signals. For each of these applications, it is desirable to obtain real-time measurements, but the accuracy of the measurements depends on the kinetics of the fluorogenic reaction being faster than the sampling frequency. Here, we describe methods to determine the in vitro kinetics for fluorogenic RNA aptamers Spinach212 and Broccoli13 using a plate reader equipped with a sample injector and to determine the cellular turn-on kinetics for Spinach2 expressed in Escherichia coli using a flow cytometer. These two RNA aptamers were chosen because they have been applied to study RNA localization2,3,4, they have been used in reporters5, 6 and biosensors7,8,9,10,11, and the corresponding dye ligands (DFHBI or DFHBI-1T) are commercially available. A summary of their in vitro properties determined in the literature is given in Table 14,13,14, which informed the protocol development (e.g., the wavelengths and dye concentrations used). These results demonstrate that the fluorogenic reactions affected by RNA aptamers are rapid and should not impede accurate measurements for the desired cell biological applications.
1. In vitro kinetics experiment
2. Cellular kinetics experiment
In vitro kinetics
The sequences of the DNA templates and primers, which are purchased as synthetic oligonucleotides, are shown in Table 2, and the reagent recipes are shown in Supplementary File 1. PCR amplification is used to scale up the amount of DNA template with the T7 promoter, which is required for the subsequent in vitro transcription (IVT) reaction. In addition, PCR amplification can be used for two purposes in the same reaction: to generate the full-length Broccoli DNA template by primer extension, as well as to scale up the DNA template.
After the IVT reaction to synthesize RNA, PAGE purification will remove any unwanted truncated transcripts, degraded products, and unreacted rNTPs from the full-length RNA product. This type of purification is preferred because truncated or degraded RNAs will cause the inaccurate determination of RNA concentrations. Since nucleotide bases absorb UV light, RNA bands and rNTPs on the gel can be visualized under UV as shadows against a fluorescent TLC plate. Thus, bands corresponding to the correct product size can be selectively extracted.
The nearest-neighbor method overestimates the extinction coefficients and, thus, the concentrations of structured RNAs since it does not account for hypochromicity due to base pairing17. Therefore, to determine accurate RNA concentrations, neutral pH thermal hydrolysis assays were performed to hydrolyze the RNA to individual NMPs18. The accurate extinction coefficient was calculated as a sum of the extinction coefficients of NMPs in the RNA sequence.
The kinetics of DFHBI binding to Spinach2 and Broccoli was determined using a plate reader assay. RNA was first renatured to ensure it would be in the correct conformation for dye binding. The reaction conditions for the plate reader kinetics assay consisted of 40 mM HEPES, pH 7.5 (KOH), 125 mM KCl, 3 mM MgCl2, 100 nM renatured RNA, and 10 µM DFHBI, and the reaction was measured at 37 °C. This temperature and concentration of MgCl2 were chosen to mimic physiological conditions19, though conditions of 28 °C and 10 mM MgCl2 may also be used for improved aptamer folding.
Both fluorogenic aptamers Spinach2 and Broccoli display two-phase association kinetics for binding to the DFHBI dye (Figure 2). The kinetics data were better fit by two-phase association than one-phase association for both aptamers (Supplementary Figure 1). The rate constants and t1/2 values for the fast and slow associations were determined by the best fit curve (Table 3). PercentFast, which describes what percent of the fluorescence turn-on magnitude is accounted for by the faster DFHBI-binding RNA population, was also determined.
Spinach2 in the binding-competent state shows faster turn-on than Broccoli (t1/2 = 1.2 s vs. 2.0 s). The second phase kinetics for both aptamers are similar (t1/2 = 180 s) and likely correspond to a common rate-limiting step for a sub-population of the sample (PercentFast = 68% and 60% for Spinach2 and Broccoli, respectively). Overall, these results show that well-folded Spinach2 and Broccoli aptamers exhibit very fast turn-on kinetics, with the initial half-maximal turn-on within 1-2 s of dye addition.
Cellular kinetics
The sequences of the DNA constructs, which are cloned into the pET31b plasmid, are shown in Table 2, and reagent recipes are shown in Supplementary File 1. The DNA constructs of fluorogenic RNA aptamers are typically contained within a tRNA scaffold for cellular experiments. The BL21 Star (DE3) E. coli strain is an expression strain with a mutation in RNase E that increases RNA stability.
The fluorescence time point measurements were recorded every 5 min for the first 45 min, followed by readings at 1 h, 1.5 h, and 2 h, giving a total of 12 time points plus the cell-only reading. Having the shortest time interval being 5 min permitted multiple biological replicates to be measured at each time point, with regular spacing between the replicate measurements of 30 s to 1 min. The total volume of cells diluted in 1x PBS solution used for the time course experiment was 1.5 mL.
The cells were gated prior to determining the mean fluorescence intensity (MFI) of the population of single cells. Gating selects an area on the scatter plot to determine the cell population that will be analyzed. This process prevents any debris or multiplet readings from being included in the analysis. For the flow cytometry analysis shown, 30,000 events were recorded, which resulted in 10,000-20,000 events analyzed after gating.
The cellular fluorescence kinetics are a function of both dye diffusion into E. coli and dye binding kinetics to the RNA aptamer within the cellular environment (Figure 1B). For cells expressing Spinach2-tRNA, it was observed that the mean fluorescence intensity (MFI) increases immediately at the "0" timepoint, due to the short time lag (in seconds) between dye addition and sample analysis (Figure 3A). Furthermore, cellular fluorescence has already reached its maximal equilibrated MFI value (40,441 ± 990) at the first time point of 5 min. In contrast, control cells show low background fluorescence (416) and no change in MFI value with DMSO addition (Figure 3B). A comparison between cells with dye and cells with no dye reveals that fluorescence activation is 98-fold ± 2 in cells. Overall, these results show that Spinach2-tRNA expressed in E. coli cells exhibits fast turn-on kinetics, with maximal turn-on within less than 5 min of dye addition.
Figure 1: Schematic of fluorescence activation. Fluorescence activation occurs upon RNA aptamers binding to dye molecules (A) in vitro and (B) in cells. Please click here to view a larger version of this figure.
Figure 2: In vitro kinetics of the fluorogenic aptamers. Representative in vitro kinetics of the fluorogenic aptamers (A,B) Spinach2 or (C,D) Broccoli modeled by two-phase association, with t = 0 s being the timepoint of DFHBI addition (final DFHBI concentration: 10 µM). Experiments were performed in triplicate. All error bars represent standard deviations from the mean. From the fit, t1/2 values were obtained for both the fast and slow association reaction components. Please click here to view a larger version of this figure.
Figure 3: Representative cellular kinetics of Spinach2 in a tRNA scaffold. (A) Timepoint analysis of tRNA-Spinach2 dye uptake over the course of 2 h. A cell-only baseline was taken prior to adding in DFHIB-1T or DMSO. Time points were taken every 5 min for the first 45 min, followed by a time point reading at 1 h, 1.5 h, and 2 h. Arrow represents when the DFHBI-1T or DMSO was added into 1x PBS solution with BL21 Star cells. The final concentration of DFHBI-1T for analysis is 50 µM. For the DMSO control, the addition of DMSO was at an equal volume (1.4 µL) used for DFHBI-1T dye addition. (B) A close-up of the DMSO control time point analysis with BL21 Star E. coli cells. Mean fluorescence intensity (MFI) indicates the overall fluorescent readout of BL21 Star cells with dye or DMSO. Data represent the mean ± standard deviation of three biological replicates. Please click here to view a larger version of this figure.
Aptamer-Dye Pair | Length (nt) | Max abs (nm) | Max em (nm) | Extinction coefficient (M-1·cm-1) | Quantum yield | Brightness | Kd (nm) | Tm (°C) | Reference |
Spinach2-DFHBI | 95 | 445 | 501 | 26100 | 0.7 | 63 | 1450 | 37 | 4 |
Spinach2-DFHBI-1T | 95 | 482 | 505 | 31000 | 0.94 | 100 | 560 | 37 | 13, 14 |
Broccoli-DFHBI-1T | 49 | 472 | 507 | 29600 | 0.94 | 96 | 360 | 48 | 13 |
Table 1: Previously published photophysical and biochemical properties of Spinach2-DFHBI4, Spinach2-DFHBI-1T13,14, and Broccoli-DFHBI-1T13.
Spinach2 + T7 promoter | 5’-CGATCCCGCGAAATTAATACGACTCACTATAGGATGTAACTGAATGAAATGGTGAA GGACGGGTCCAGTAGGCTGCTTCGGCAGCCTACTTGTTGAGTAGAGTGTGAGCTCC GTAACTAGTTACATC-3’ |
||
Broccoli + T7 promoter | 5’-CGATCCCGCGAAATTAATACGACTCACTATAGgagacggtcgg gtccagatattcgtatctgtcgagtagagtgtgggctc-3’ |
||
tRNA-Spinach2 construct (in pET31b plasmid) | 5'-CGATCCCGCGAAATTAATACGACTCACTATAGGGGCCCGGATAGCTCAGTCGGT AGAGCAGCGGCCGGATGTAACTGAATGAAATGGTGAAGGACGGGTCCAGTAGGCT GCTTCGGCAGCCTACTTGTTGAGTAGAGTGTGAGCTCCGTAACTAGTTACATCCGG CCGCGGGTCCAGGGTTCAAGTCCCTGTTCGGGCGCCA TAGCATAACCCCTTGGGGCCTCTAAACGGGTCTTGAGGGGTTTTTTG-3' |
||
Spinach2 Forward Primer | 5’-CGATCCCGCGAAATTAATACGACTCACTATAG-3’ | ||
Spinach2 Reverse Primer | 5’-GATGTAACTAGTTACGGAGC-3’ | ||
Broccoli Forward Primer | 5’-CGATCCCGCGAAATTAATACGACTCACTATAGgagacggtcgggtccagatattcgtatctg-3’ | ||
Broccoli Reverse Primer | 5’-gagcccacactctactcgacagatacgaatatctggacccgaccgtctc-3’ |
Table 2: DNA sequence table containing DNA sequences and primers used for in vitro and cellular kinetics studies. Bold= T7 promoter; Underlined = tRNA scaffold; Caps = Spinach2; lowercase = Broccoli; Bold italics = T7 terminator.
Aptamer | Fast t1/2 (s) | Slow t1/2 (s) | KFast (s-1) | KSlow (s-1) | Percent Fast |
Spinach2 | 1.2 ± 0.2 | 180 ± 10 | 0.56 ± 0.07 | 0.0039 ± 0.0002 | 68 ± 5 |
Broccoli | 2.0 ± 0.2 | 180 ± 30 | 0.35 ± 0.05 | 0.0039 ± 0.0006 | 60 ± 3 |
Table 3: In vitro kinetics values of the Spinach2 and Broccoli aptamers derived from fitted data. The data are reported as the mean ± standard deviation of three replicates.
Supplementary Figure 1: Representative in vitro kinetics of the fluorogenic aptamers. Representative in vitro kinetics of the fluorogenic aptamers (A,C) Spinach2 or (B,D) Broccoli modeled by one-phase association at (A,B) 600 s or (C,D) 20 s measurement times, with arrows indicating the timepoint of DFHBI addition (final DFHBI concentration: 10 µM). Experiments were performed in triplicate. Overall, these data are less well fit by a one-phase association model than a two-phase association model when fluorescence signal is monitored for a longer duration. Please click here to download this File.
Supplementary File 1: Recipes for in vitro kinetics experiment. Please click here to download this File.
For the in vitro kinetics experiment, the same general protocol can be modified to measure the in vitro kinetics of an RNA-based fluorescent biosensor containing both a ligand-binding and fluorophore-binding domain8. In this case, the RNA should be incubated with the fluorophore prior to measurements upon injecting the ligand in order to obtain ligand response kinetics. If high variability is observed between the replicates, one can troubleshoot by checking that each sample is allowed to equilibrate for the same amount of time in the 96-well plate before measurement. Each sample or replicate should be individually prepared in a well and measured right after the 15 min equilibration step, rather than preparing all samples at once.
For the cellular kinetics experiment, the protocol can be modified for shorter or longer time courses, but it is critical to plan out the number of biological replicates and adjust the needed cell solution volume. It is recommended to space out each biological replicate reading between 30 s to 1 min to have adequate time to perform the steps carefully. Another modification is to test a different fluorogenic dye that does not bind the RNA aptamer as an alternative negative control, which should not show fluorescence activation over the background. If inconsistent results are observed, one can troubleshoot by checking that the flow cytometer is properly cleaned following the manufacturer's protocol between different experimental runs to prevent any bleed-over of cells or dyes from the previous run to the next.
While the in vitro method presented is useful for comparing the kinetics between fluorogenic aptamers or RNA-based fluorogenic biosensors, the kinetic values obtained may change depending on the temperature, magnesium concentration, or other buffer components used. Also, while this method provides well-defined conditions that have been used previously to characterize different fluorogenic RNA systems, the intracellular environment cannot be perfectly represented due to the presence of other biological macromolecules.
Whereas the fluorescence plate reader equipped with a programmable injector has no dead time for data acquisition, the flow cytometer instrument has limited temporal accuracy due to observable dead time. There is a ~5 s lag between when the "Record" button is clicked and when data acquisition starts. An additional ~5 s lag occurs for the instrument to measure 30,000 events; this sample acquisition time will vary slightly depending on how dilute the cells are in 1x PBS.
Another potential limitation to cellular experiments is the cell viability in 1x PBS. For extended time point analyses, cell viability can be checked using propidium iodide to stain dead cells20. Dye aggregation can also limit the accuracy of fluorescence measurements made by the flow cytometer. Dyes with very limited solubility in aqueous solutions can aggregate and appear as particles large enough to be counted as cells on the flow cytometer. Thus, it is important to run dye-only experimental controls to check for aggregates in the gated region.
Previously, it was shown that Broccoli has comparable brightness to Spinach2 at 1 mM Mg2+ in vitro, but Broccoli-tRNA exhibits ~two-fold greater fluorescence intensity in live E. coli compared to Spinach2-tRNA13. To our knowledge, the dye-binding kinetics for Spinach2 and Broccoli fluorogenic aptamers have not been compared before and modeled by a two-phase association. The initial fast rate constants for both RNA aptamers support that the dye binding pocket is pre-folded and no structural changes are needed for the dye to bind, which is consistent with X-ray crystallography and UV-melting experiments21,22. The second phase with a slower rate constant has not been previously reported because other experiments such as stopped-flow and fluorescence lifetime measurements analyzed the Spinach aptamer for a shorter duration (20 s and 300 s)23,24. The much slower second phase results in an observed biexponential increase in fluorescence when data are analyzed for 600 s. This slow step can be attributed to either a rate-limiting refolding step from a binding-incompetent to binding-competent RNA state or a rate-limiting photoconversion step from trans a cis forms of the bound dye. The latter mechanism was previously modeled to give a biexponential fluorescence profile24 and is supported by a recent analysis of the difference between the absorption and excitation spectra on the related aptamer, Baby Spinach25.
The overall significance of the in vitro findings is that they show that dye association to the fluorogenic RNA aptamer does not limit real-time RNA localization and gene expression studies. For RNA-based fluorescent biosensors that employ Spinach2, the measured turn-on kinetics are similar to the second phase kinetics measured here10 because the biosensors require a refolding step and, thus, should be sufficiently rapid to enable near-real-time signaling studies.
It was expected that the cellular kinetics would be different from the observed in vitro kinetics for Spinach2. One key difference is that there is an additional step of dye diffusion into the E. coli cells, which involves crossing the outer and inner membranes. In addition, the cellular environment poses different conditions for the dye-aptamer association in terms of molecular crowding, ion composition, and concentrations, as well as RNA and dye concentrations.
The overall significance of the results is that cellular fluorescence reaches maximum signal in less than 5 min and remains stable for at least 2 h, which enables real-time RNA localization and gene expression studies in this time range. For an RNA-based biosensor that employs Spinach2, we previously showed that a significant fluorescence response could be observed within 4-5 min of ligand addition but that reaching the maximal signal takes longer (15-30 min)8. Taken together, these findings indicate that dye diffusion into cells is not the practical rate-limiting step for in vivo experiments with RNA-based biosensors. Finally, this experimental protocol can be applied to analyze other fluorogenic RNA systems in cells.
The experimental protocols presented here can be applied to analyze other fluorogenic RNA systems. Beyond the two aptamers analyzed in this study, Spinach2 and Broccoli, other fluorogenic RNA systems have been developed that provide different emission profiles, improved photostability, tighter binding affinities, and the ability to change fluorophores (recently reviewed1). In addition to their fluorescence properties, benchmarking the turn-on kinetics for these systems in vitro and in cells is important to assess their suitability for different cell biological applications. The results also may support structural pre-folding or rearrangement of the aptamer. As discussed, with some modifications, these protocols have also been applied to analyze RNA-based biosensors8.
The authors have nothing to disclose.
This work was supported by the following grants to MCH: NSF-BSF 1815508 and NIH R01 GM124589. MRM was partially supported by training grant NIH T32 GM122740.
Agarose | Thermo Fischer Scientific | BP160500 | |
Agarose gel electrophoresis equipment | Thermo Fischer Scientific | B1A-BP | |
Alpha D-(+)-lactose monohydrate | Thermo Fischer Scientific | 18-600-440 | |
Amber 1.5 mL microcentrifuge tubes | Thermo Fischer Scientific | 22431021 | |
Ammonium persulfate (APS) | Sigma-Aldrich | A3678 | |
Ammonium sulfate ((NH4)2SO4) | Sigma-Aldrich | A4418 | |
Attune NxT Flow cytometer | Thermo Fischer Scientific | A24861 | |
Attune 1x Focusing Fluid | Thermo Fischer Scientific | A24904 | |
Attune Shutdown Solution | Thermo Fischer Scientific | A24975 | |
Attune Performance Tracking Beads | Thermo Fischer Scientific | 4449754 | |
Attune Wash Solution | Thermo Fischer Scientific | J24974 | |
Boric acid | Sigma-Aldrich | B6768 | |
Bromophenol blue | Sigma-Aldrich | B0126 | |
Carbenicillin disodium salt | Sigma-Aldrich | C3416 | |
Chlorine Bleach | Amazon | B07J6FJR8D | |
Corning Costar 96-well plate | Daigger Scientific | EF86610A | |
Culture Tubes, 12 mm x 75 mm, 5 mL with attached dual position cap | Globe Scientific | 05-402-31 | |
DFHBI | Sigma-Aldrich | SML1627 | |
DFHBI-1T | Sigma-Aldrich | SML2697 | |
D-Glucose (anhydrous) | Acros Organics | AC410955000 | |
Dimethyl sulfoxide (DMSO) | Sigma-Aldrich | D8418 | |
Dithiothreitol (DTT) | Sigma-Aldrich | DTT-RO | |
DNA loading dye | New England Biolabs | B7025S | |
DNA LoBind Tubes (2.0 mL) | Eppendorf | 22431048 | |
dNTPs: dATP, dCTP, dGTP, dTTP | New England Biolabs | N0446S | |
EDTA, pH 8.0 | Gibco, Life Technologies | AM9260G | |
Ethanol (EtOH) | Sigma-Aldrich | E7023 | |
Filter-tip micropipettor tips | Thermo Fischer Scientific | AM12635, AM12648, AM12655, AM12665 | |
FlowJo Software | BD Biosciences | N/A | FlowJo v10 Software |
Fluorescent plate reader with heating control | VWR | 10014-924 | |
Gel electrophoresis power supply | Thermo Fischer Scientific | EC3000XL2 | |
Glycerol | Sigma-Aldrich | G5516 | |
Glycogen AM95010 | Thermo Fischer Scientific | AM95010 | |
GraphPad Prism | Dotmatics | N/A | Analysis software from Academic Group License |
Heat block | Thomas Scientific | 1159Z11 | |
HEPES | Sigma-Aldrich | H-4034 | |
Inorganic pyrophosphatase | Sigma-Aldrich | I1643-500UN | |
Low Molecular Weight DNA Ladder | New England Biolabs | N3233L | Supplied with free vial of Gel Loading Dye, Purple (6x), no SDS (NEB #B7025). |
Magnesium chloride hexahydrate (MgCl2) | Sigma-Aldrich | M2670 | |
Magnesium sulfate (MgSO4) | Fisher Scientific | MFCD00011110 | |
Microcentrifuge tubes (1.5 mL) | Eppendorf | 22363204 | |
Microcentrifuge with temperature control | Marshall Scientific | EP-5415R | |
Micropipettors | Gilson | FA10001M, FA10003M, FA10005M, FA10006M | |
Micropipettor tips | Sigma-Aldrich | Z369004, AXYT200CR, AXYT1000CR | |
Millipore water filter with BioPak unit | Sigma-Aldrich | CDUFBI001, ZRQSVR3WW | |
Narrow micropipettor pipette tips | DOT Scientific | RN005R-LRS | |
PBS, 10x | Thermo Fischer Scientific | BP39920 | |
PCR clean-up kit | Qiagen | 28181 | |
PCR primers and templates | Integrated DNA technologies | ||
PCR thermocycler for thin-walled PCR tubes | Bio-Rad | 1851148 | |
PCR thermocycler for 0.5 mL tubes | Techne | 5PRIME/C | |
pET31b-T7-Spinach2 Plasmid | Addgene | Plasmid #79783 | |
Phusion High-Fidelity DNA polymerase | New England Biolabs | M0530L | Purchase of Phusion High-Fideldity Enzyme is supplied with 5x Phusion HF Buffer, 5x Phusion GC Buffer, and MgCl2 and DMSO solutions. |
Polyacrylamide gel electrophoresis gel comb, C.B.S. Scientific | C.B.S. Scientific | VGC-1508 | |
Polyacrylamide gel electrophoresis equipment | C.B.S. Scientific | ASG-250 | |
Potassium chloride (KCl) | Sigma-Aldrich | P9333 | |
Potassium phosphate monobasic | Sigma-Aldrich | P5655 | |
Razor blades | Genesee Scientific | 38-101 | |
rNTPs: ATP, CTP, GTP, UTP | New England Biolabs | N0450L | |
SDS | Sigma-Aldrich | L3771 | |
Short wave UV light source | Thermo Fischer Scientific | 11758221 | |
Sodium carbonate (Na2CO3) | Sigma-Aldrich | S7795 | |
Sodium chloride (NaCl) | Sigma-Aldrich | S7653 | |
Sodium hydroxide (NaOH) | Sigma-Aldrich | S8045 | |
Sodium phosphate dibasic, anhydrous | Thermo Fischer Scientific | S375-500 | |
SoftMax Pro | Molecular Devices | N/A | SoftMax Pro 6.5.1 (platereader software) obtained through Academic Group License |
Sterile filter units | Thermo Fischer Scientific | 09-741-88 | |
Sucrose | Sigma-Aldrich | S0389 | |
SYBR Safe DNA gel stain | Thermo Fischer Scientific | S33102 | |
TAE buffer for agarose gel electrophoresis | Thermo Fischer Scientific | AM9869 | |
Tetramethylethylenediamine (TEMED) | Sigma-Aldrich | T9281 | |
Tris base | Sigma-Aldrich | TRIS-RO | |
Tryptone (granulated) | Thermo Fischer Scientific | M0251S | |
T7 RNA polymerase | New England Biolabs | M0251S | |
Urea-PAGE Gel system | National Diagnostics | EC-833 | |
UV fluorescent TLC plate | Sigma-Aldrich | 1.05789.0001 | |
UV/Vis spectrophotometer | Thermo Fischer Scientific | ND-8000-GL | |
Vortex mixer | Thermo Fischer Scientific | 2215415 | |
Xylene cyanol | Sigma-Aldrich | X4126 | |
Yeast Extract (Granulated) | Thermo Fischer Scientific | BP9727-2 |