Summary

In vitro Transcription and Capping of Gaussia Luciferase mRNA Followed by HeLa Cell Transfection

Published: March 26, 2012
doi:

Summary

This method describes high yield in vitro synthesis of both capped and uncapped mRNA from a linearized plasmid containing the Gaussia luciferase (GLuc) gene. The RNA is purified and a fraction of the uncapped RNA is enzymatically capped using the Vaccinia virus capping enzyme. In the final step, the mRNA is transfected into HeLa cells and cell culture supernatants are assayed for luciferase activity.

Abstract

In vitro transcription is the synthesis of RNA transcripts by RNA polymerase from a linear DNA template containing the corresponding promoter sequence (T7, T3, SP6) and the gene to be transcribed (Figure 1A). A typical transcription reaction consists of the template DNA, RNA polymerase, ribonucleotide triphosphates, RNase inhibitor and buffer containing Mg2+ ions.

Large amounts of high quality RNA are often required for a variety of applications. Use of in vitro transcription has been reported for RNA structure and function studies such as splicing1, RNAi experiments in mammalian cells2, antisense RNA amplification by the “Eberwine method”3, microarray analysis4 and for RNA vaccine studies5. The technique can also be used for producing radiolabeled and dye labeled probes6. Warren, et al. recently reported reprogramming of human cells by transfection with in vitro transcribed capped RNA7. The T7 High Yield RNA Synthesis Kit from New England Biolabs has been designed to synthesize up to 180 μg RNA per 20 μl reaction. RNA of length up to 10kb has been successfully transcribed using this kit. Linearized plasmid DNA, PCR products and synthetic DNA oligonucleotides can be used as templates for transcription as long as they have the T7 promoter sequence upstream of the gene to be transcribed.

Addition of a 5′ end cap structure to the RNA is an important process in eukaryotes. It is essential for RNA stability8, efficient translation9, nuclear transport10 and splicing11. The process involves addition of a 7-methylguanosine cap at the 5′ triphosphate end of the RNA. RNA capping can be carried out post-transcriptionally using capping enzymes or co-transcriptionally using cap analogs. In the enzymatic method, the mRNA is capped using the Vaccinia virus capping enzyme12,13. The enzyme adds on a 7-methylguanosine cap at the 5′ end of the RNA using GTP and S-adenosyl methionine as donors (cap 0 structure). Both methods yield functionally active capped RNA suitable for transfection or other applications14 such as generating viral genomic RNA for reverse-genetic systems15 and crystallographic studies of cap binding proteins such as eIF4E16.

In the method described below, the T7 High Yield RNA Synthesis Kit from NEB is used to synthesize capped and uncapped RNA transcripts of Gaussia luciferase (GLuc) and Cypridina luciferase (CLuc). A portion of the uncapped GLuc RNA is capped using the Vaccinia Capping System (NEB). A linearized plasmid containing the GLuc or CLuc gene and T7 promoter is used as the template DNA. The transcribed RNA is transfected into HeLa cells and cell culture supernatants are assayed for luciferase activity. Capped CLuc RNA is used as the internal control to normalize GLuc expression.

Protocol

RNases are commonly present on skin, hair, dust, laboratory surfaces, solutions, etc. Wear gloves and clean bench surface, pipettes etc. thoroughly before use to avoid RNase contamination. Use of nuclease- free pipette tips, tubes, glassware and reagents is strongly recommended.

1. In vitro Transcription using the T7 High-yield RNA Synthesis Kit

The DNA template for the transcription reaction is a linearized plasmid containing the Gaussia luciferase gene and a T7 promoter upstream of the coding sequence (Figure 1B).

  1. Thaw the components from the T7 High Yield RNA Synthesis kit and keep on ice.
  2. For uncapped RNA, set up the reaction at room temperature in the following order:
Component Volume (μl) Final
Nuclease free water* X  
10X Reaction Buffer 2 1X
ATP (100 mM) 2 10mM
CTP (100 mM) 2 10mM
UTP (100 mM) 2 10mM
GTP (100 mM) 2 10mM
Template DNA * X 1 μg
T7 RNA Polymerase Mix 2  
Total 20  

*Add 1 μg DNA and make up the total reaction volume to 20 μl with nuclease free water. The amount of water to be added will vary based on the concentration of the template DNA.

  1. For capped RNA: Set up the reaction at room temperature in the following order:
Component Volume (μl) Final
Nuclease free water* X  
10X Reaction Buffer 2 1X
ATP (100 mM) 2 10mM
CTP (100 mM) 2 10mM
UTP (100 mM) 2 10mM
GTP (20 mM) 2 2mM
3´-0-Me-m7G(5′)ppp(5′)G cap analog (ARCA)(40mM) 4 8mM
Template DNA* X 1 μg
T7 RNA Polymerase Mix 2  
Total 20  

*Add 1 μg DNA and make up the total reaction volume to 20 μl with nuclease free water. The amount of water to be added will vary based on the concentration of the template DNA.

  1. Mix well by vortexing and incubate the reactions at 37 °C for 2 hours in a dry air incubator.
  2. Using steps 1.3-1.4, synthesize capped transcripts of Cypridina luciferase (CLuc) from a linearized plasmid containing the CLuc gene. This mRNA will be co-transfected with the capped and uncapped GLuc mRNA for normalization of GLuc expression.

2. Removal of Template DNA

The transcription reactions are treated with DNase I to remove the DNA template before proceeding with purification.

  1. Add 70 μl nuclease free water to the transcription reactions followed by 10 μl of DNase I reaction buffer.
  2. Add 2 μl DNase I to the reactions.
  3. Incubate at 37 °C for 15 minutes in a dry air incubator.

3. Column Purification of Capped and Uncapped RNA

  1. Purify the capped and uncapped RNA using the MEGAclearKit as per the manufacturer’s instructions (any spin column based RNA purification kit may be used).
  2. Quantify the RNA using a NanoDrop Spectrophotometer.
  3. As per the manufacturer’s instructions, assess RNA sample quality using the Agilent RNA 6000 Nano Kit and Agilent 2100 Bioanalyzer.

4. RNA Capping using the Vaccinia Capping System

  1. Take 10 μg of the purified uncapped GLuc mRNA.

A standard capping reaction can cap up to 10 μg (100nt or larger) RNA. If a larger amount of RNA needs to be capped the reaction can be scaled up accordingly.

  1. Increase the volume to 15 μl using nuclease free water.
  2. Heat the RNA at 65 °C for 10 minutes to remove secondary structures. Place on ice for 5 minutes.
  3. To set up the capping reaction, add 2 μl 10X Capping Buffer, 1 μl GTP (10 mM), 1 μl freshly diluted S-adenosyl methionine (2 mM) and 1 μl (10 units) Vaccinia capping enzyme to the 15 μl denatured RNA.
  4. Mix well by gently vortexing and incubate the reaction at 37 °C for 30 minutes in a dry air incubator.

5. Column Purification of Capped RNA

  1. Purify the capped RNA using the MEGAclear Kit (any spin column based RNA purification kit may be used).
  2. As per the manufacturer’s instructions, assess RNA sample quality using the Agilent RNA 6000 Nano Kit and Agilent 2100 Bioanalyzer.

6. HeLa Cell Transfection using TransIT mRNA Transfection Kit

  1. Plate HeLa cells in a 48-well plate in 150 μl Dulbecco’s Modified Eagle’s Medium (DMEM), High Glucose, supplemented with 10% fetal bovine serum (0.7-2.3 × 105 cells/well).
  2. Incubate for 16-24 hours at 37 °C such that the cells are 60-90% confluent.
  3. Dilute the GLuc (capped and uncapped) and CLuc RNA to 100 ng/μl concentration.

Each transfection is done in replicates of 8.

  1. Set up 8 eppendorf tubes. To each tube add 1 μl uncapped GLuc RNA, 1 μl capped CLuc RNA (for normalization) and 25 μl of serum free DMEM. Mix well.
  2. Set up 8 eppendorf tubes. To each tube add 1 μl capped GLuc RNA (cap analog), 1 μl capped CLuc RNA (for normalization) and 25 μl of serum free DMEM. Mix well.
  3. Set up 8 eppendorf tubes. To each tube add 1 μl capped GLuc RNA (Vaccinia), 1 μl capped CLuc RNA (for normalization) and 25 μl of serum free DMEM. Mix well.
  4. Add 0.2 μl mRNA Boost Reagent to the first set of 8 tubes and mix.
  5. Add 0.2 μl TransIT mRNA Reagent to the first set of 8 tubes and mix.
  6. Incubate at room temperature for 2-5 minutes. (Do not incubate longer than 5 minutes).
  7. Add the transfection mixture drop wise to the wells containing HeLa cell cultures (refer Figure 3 for plate set-up).
  8. Repeat steps 7 through 10 with the 2nd and 3rd sets of 8 tubes.
  9. Incubate overnight (16 hours) at 37 °C in 5% CO2.

7. Gaussia Luciferase (GLuc) Assay

Assay the supernatant from each well for GLuc activity using the BioLux Gaussia Luciferase Assay Kit as follows:

  1. Prepare fresh assay solution by adding 15 μl of BioLux GLuc Substrate to 1.5 ml of BioLux GLuc Assay Buffer (50 μl assay solution required per sample). Prepare enough for samples and for priming luminometer injector (refer to manufacturer’s instructions).
  2. Mix well by inverting the tube several times (do not vortex).

Luminescence is measured using the Centro LB 960 microplate luminometer from Berthold Technologies.

  1. Set the luminometer to 50 μl injection volume and 2-10 seconds integration.
  2. Add 10 μl of the cell culture supernatant from each well into a 96-well black plate.
  3. Prime the injector with the assay solution and proceed with measurement of luminescence.
  4. Values obtained from untransfected wells will be used as negative controls.

8. Cypridina Luciferase (CLuc) Assay

Assay the supernatant from each well for CLuc activity using the BioLux Cypridina Luciferase Assay Kit as follows:

  1. Prepare fresh reconstituted substrate (100x) according to instructions given in the kit manual.
  2. Thaw the BioLux Cypridina Luciferase Assay Buffer and mix well (protect from light).
  3. To prepare the CLuc assay solution, add 15 μl of the reconstituted substrate (100x) to 1.5 ml of BioLux Cypridina Luciferase Assay Buffer (50 μl assay solution required per sample). Prepare enough for samples and for priming luminometer injector (refer to manufacturer’s instructions).
  4. Mix well by inverting the tube several times (do not vortex).
  5. Keep the solution at room temperature for 30 minutes (protect from light).

Luminescence is measured using the Centro LB 960 microplate luminometer from Berthold Technologies.

  1. Set the luminometer to 50 μl injection, 1-2 seconds delay and 2-10 seconds integration.
  2. Add 10 μl of the cell culture supernatant from each well into a 96-well black plate.
  3. Prime the injector with the CLuc assay solution and measure luminescence.
  4. Values obtained from untransfected wells will be used as negative controls.

9. Representative Results

The T7 High Yield RNA Synthesis Kit can produce up to 180 μg uncapped RNA and 40 to 50 μg of capped RNA per 20 μl reaction. When analyzed on the Agilent 2100 Bioanalyzer, good quality, intact RNA should show a single, sharp peak representing the RNA transcript. A broad peak or multiple peaks indicate RNA degradation. It is also important to verify the size of the RNA. RNA transcripts of a longer length than expected may be due to incomplete digestion of the template plasmid DNA. RNA degradation and lower yield are usually a result of contaminants introduced into the reaction from the template DNA. Figure 2 is an example of the electropherogram and gel image obtained after running high quality, intact RNA on the Bioanalyzer.

Transfection of HeLa cells with both capped and uncapped GLuc RNA is followed by incubation and assaying cell culture supernatants for luciferase activity. The 5′ cap structure is important for protecting the RNA against exonuclease degradation8 and for promoting translation initiation9 of the mRNA. Therefore, RNA capping is an essential step for transfection experiments. The co-transcriptional (cap analog) method yields approximately 40 μg RNA that is 80% capped. The protocol utilizing Vaccinia capping enzyme caps up to 10 μg RNA (100 nt or larger) per reaction with nearly 100% efficiency.

Figure 4 depicts the difference in luciferase expression between cultures transfected with capped and uncapped RNA samples. It can be clearly seen that cell cultures transfected with capped RNA show much higher expression of luciferase as compared to those transfected with uncapped RNA (which show no luciferase activity). In addition, Figure 4 also validates that both capping techniques, using cap analog and using the Vaccinia capping enzyme, successfully produce functional, capped RNA transcripts that can be translated into protein. The two tailed p-value obtained from the t-test was 0.2583 which indicates that there is no significant statistical difference between the luminescence data from the two capping methods.

Figure 1.

Figure 1A. RNA Synthesis by T7 RNA Polymerase

Figure 2.
Figure 1B. pCMV-GLuc vector containing GLuc gene and T7 promoter.

Figure 2.
Figure 2. Bioanalyzer electropherograms and gel- image of capped and uncapped RNA . The X-axis is the size of the RNA in nucleotides (nt) and the Y-axis represents fluorescence units (FU). A) Electropherogram of GLuc mRNA (uncapped) after purification. B) Electropherogram of GLuc mRNA (capped using Vaccinia capping enzyme). C) Electropherogram of GLuc mRNA (capped co-transcriptionally using cap analog). D) Gel-like image generated by the Bioanalyzer. The ‘L’ lane is the RNA ladder, Lane 1 is uncapped GLuc mRNA, Lane 2 is GLuc mRNA capped using the cap analog and Lane 3 is the GLuc RNA capped using Vaccinia capping enzyme.

Figure 3.
Figure 3. Example of plate set-up for HeLa cell transfection . Each well consists of plated HeLa cells that are 60-90% confluent. The transfection mix consisting of the appropriate GLuc RNA (uncapped, capped with cap analog or capped with Vaccinia capping enzyme), capped CLuc RNA (for normalization), mRNA Boost Reagent and TransIT mRNA Reagent is added to each well. Each transfection is done in replicates of 8 (same colored wells in the figure).

Figure 4.
Figure 4.GLuc expression in HeLa cells. Purified capped and uncapped GLuc mRNA was transfected into HeLa cells and incubated overnight (16 hrs) at 37 °C. Cell culture supernatants from each well were assayed for GLuc and CLuc activity and luminescence values were recorded. The GLuc luminescence values were normalized to the luminescence values of capped CLuc RNA.

Equation 1

* Luminescence from untransfected cells was subtracted from GLuc and CLuc values before normalization.

Trademarks

BioLux is a trademark of New England Biolabs, Inc.

TransIT is a registered trademark of Mirus Bio LLC.

MEGAclear is a trademark of Ambion.

Discussion

In vitro transcription is a useful method for obtaining high yields of RNA for a variety of applications. The major advantage of using the T7 High Yield RNA Synthesis Kit is that its formulation has been optimized to achieve high yields of RNA. In addition, the reagents provided in the kit are free of contaminating nucleases, resulting in synthesis of high quality, intact RNA transcripts. The kit is designed for high stability and flexibility such that it can be used for synthesizing mRNA, dye labeled RNA, high specific activity radiolabeled probes and capped RNA. The kit manual includes a list of specific protocols and additional materials required for each of these applications. It also includes technical information on using PCR products and synthetic DNA oligonucleotides as templates for transcription. It is important to note that the transcription kit can only utilize DNA templates containing a T7 promoter.

The method described in this article demonstrates post-transcriptional RNA capping using Vaccinia capping enzyme, as well as co-transcriptional capping using RNA cap structure analog. We have shown that both methods synthesize capped RNA that is functionally active post-transfection. The 5′ cap structure improves stability of the RNA and translation efficiency, and hence is important for microinjection11 and transfection7 experiments. The co-transcriptional capping method generates 40-50 μg of ~80% capped RNA. It is important to note that using 3′-0-Me-m7G(5′)ppp(5′)G RNA cap analog (ARCA), which is blocked at the 3′-hydroxyl of the m7G ensures incorporation of the cap in the correct orientation17. To cap larger quantities of RNA it is possible to scale up the standard reactions for both capping methods. However, using the Vaccinia Capping System would be a more feasible option cost-wise since co-transcriptional capping utilizes cap analog, which is a relatively expensive component. The Vaccinia Capping System is also a better method since it has capping efficiency of almost 100%.

The RNA capping methods described above synthesize RNA with a cap 0 structure at the 5′ end. Cap 1 structure involves additional methylation at the 2′-O position of the ribose sugar of the first nucleotide at the ‘ end of the RNA. The cap 1 structure has been reported to enhance RNA translation efficiency18 and can be incorporated by using 2′-O- Methyltransferase20, 21.

The method described in this paper can be used to transcribe, cap and transfect any desired mRNA. The luciferases GLuc and CLuc were specifically used in this protocol due to their many advantages. They are directly secreted into the cell medium, therefore avoiding need for cell lysis. Also, they generate high bioluminescent signal intensity, and the activity assays are highly sensitive and easy to perform. It is important to note that the GLuc expression in the cells can be influenced by various factors other than the functionality of the RNA itself. Some examples are pipetting errors, varying cell numbers per well, transfection efficiency etc. Data normalization is used to account for these factors. In our protocol, we co-transfect CLuc RNA as an internal control with the GLuc RNA. When GLuc luminescence is divided by the CLuc control values, it gets normalized for the errors and variability in transfection19.

Disclosures

The authors have nothing to disclose.

Acknowledgements

Dongxian Yue, Brett Robb, George Tzertzinis, Tanya Bhatia, Breton Hornblower.

Materials

Name of the reagent Company Catalogue number Comments
T7 High Yield RNA Synthesis Kit New England Biolabs E2040S
3´-0-Me-m7G(5′)ppp(5′)G RNA Cap Structure Analog New England Biolabs S1411S
DNase I (RNase-free) New England Biolabs M0303S
Vaccinia Capping System New England Biolabs M2080S
MEGAclear Kit Ambion AM1908
NanoDrop Spectrophotometer Thermo Scientific
Agilent RNA 6000 Nano Kit Agilent Technologies 5067-1511
Agilent 2100 Bioanalyzer Agilent Technologies G2939AA
TransIT mRNA Transfection Kit Mirus Bio LLC MIR2250
HyClone* Classical Liquid Media: Dulbecco’s Modified Eagle’s Medium, High Glucose Thermo Scientific SH30285.01
HyClone Non-essential Amino Acids Thermo Scientific SH30238.01
Centro LB 960 Berthold Technologies
BioLux Gaussia Luciferase Assay Kit New England Biolabs E3300S
BioLux Cypridina Luciferase Assay Kit New England Biolabs E3309S
RNase Inhibitor, Murine New England Biolabs M0314
RNase Inhibitor, Human Placenta New England Biolabs M0307
pCMV-GLuc Control Plasmid New England Biolabs N8081

References

  1. Lazarev, D., Manley, J. L. Concurrent splicing and transcription are not sufficient to enhance splicing efficiency. RNA. 13, 1546-1557 (2007).
  2. Donze, O., Picard, D. RNA interference in mammalian cells using siRNAs synthesized with T7. RNA Polymerase. Nucl. Acids Res. 30, 10-46 (2002).
  3. Van Gelder, R. N. Amplified RNA synthesized from limited quantities of heterogeneous cDNA. Proc. Nati. Acad. Sci. U.S.A. 87, 1663-1667 (1990).
  4. Schneider, J. Systematic analysis of T7 RNA polymerase based in vitro linear RNA amplification for use in microarray experiments. BMC Genomics. 5, 29-29 (2004).
  5. Conry, R. M. Characterization of a messenger RNA polynucleotide vaccine vector. 암 연구학. 55, 1397-1400 (1995).
  6. Huang, F., Wang, G., Coleman, T., Li, N. Synthesis of adenosine derivatives as transcription initiators and preparation of 5′ fluorescein- and biotin-labeled RNA through one-step transcription. RNA. 9, 1562-1570 (2003).
  7. Warren, L. Highly efficient reprogramming to pluripotency and directed differentiation of human cells with synthetic modified mRNA. Cell Stem Cell. 7, 618-630 (2010).
  8. Furuichi, Y., LaFiandra, A., Shatkin, A. J. 5′-Terminal structure and mRNA stability. Nature. 266, 235-239 (1977).
  9. Topisirovic, I., Svitkin, Y. V., Sonenberg, N., Shatkin, A. J. Cap and cap binding proteins in the control of gene expression. Wiley Interdisciplinary Reviews. 2, 277-298 (2011).
  10. Lewis, J. D., Izaurflde, E. The Role of the Cap Structure in RNA Processing and Nuclear Export. Eur. J. Biochem. 247, 461-469 (1997).
  11. Inoue, K., Ohno, M., Sakamoto, H., Shimura, Y. Effect of the cap structure on pre-mRNA splicing in Xenopus oocyte nuclei. Genes Dev. 3, 1472-1479 (1989).
  12. Martin, S. A., Paoletti, E., Moss, B. Purification of mRNA guanylyltransferase and mRNA (guanine 7-)methyltransferase from vaccinia virus. J. Biol. Chem. 250, 9322-9329 (1975).
  13. Martin, S. A., Moss, B. Modification of RNA by mRNA guanylytransferase and mRNA (guanine-7-)methyl-transferase from vaccinia virions. J. Biol. Chem. 250, 9330-9335 (1975).
  14. Shuman, S., Moss, B. Purification and use of vaccinia virus mRNA capping enzyme. Meth. Enzymol. 181, 170-180 (1990).
  15. Thiel, V., Herold, J., Scelle, B., Siddell, S. G. Infectious RNA transcribed in vitro from a cDNA copy of the human coronavirus genome cloned in vaccinia virus. J. Gen. Virol. 82, 1273-1281 (2001).
  16. Marcotrigiano, J., Gingras, A. -. C., Sonenberg, N., Burley, S. K. Cocrystal Structure of the Messenger RNA 5′ Cap-Binding Protein (eIF4E) Bound to 7-methyl-GDP. Cell. 89, 951-961 (1997).
  17. Stepinski, J. Synthesis and properties of mRNAs containing the novel “anti-reverse” cap analogs 7-methyl (3′-O-methyl)GpppG and 7-methyl (3′-deoxy) GpppG. RNA. 7, 1486-1495 (2001).
  18. Kuge, H., Brownlee, G. G., Gershon, P. D., Richter, J. D. Cap ribose methylation of c-mos mRNA stimulates translation and oocyte maturation in Xenopus laevis. Nucl. Acids Res. 26, 3208-3214 (1998).
  19. Schagat, T., Paguio, A., Kopish, K. Normalizing Genetic Reporter Assays: Approaches and Considerations for Increasing Consistency and Statistical Significance. Cell Notes. 17, 9-12 (2007).
  20. Barbosa, E., Moss, B. mRNA (nucleoside-2′-) – methyltransferase from Vaccinia Virus. J. Biol. Chem. 253, 7698-7702 (1978).
  21. Lockless, S. W. Recognition of capped RNA substrates by VP39, the vaccinia virus-encoded mRNA cap-specific 2′-O-methyltransferase. 생화학. 37, 8564-8574 (1998).

Play Video

Cite This Article
Jani, B., Fuchs, R. In vitro Transcription and Capping of Gaussia Luciferase mRNA Followed by HeLa Cell Transfection. J. Vis. Exp. (61), e3702, doi:10.3791/3702 (2012).

View Video