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The process for mRNA research and discovery requires flexible products and technologies to meet many of your diverse needs. To effectively facilitate mRNA discovery, Thermo Fisher Scientific offers a variety of products that span the entire portfolio from target gene identification and synthesis, plasmid production, in vitro transcription, and delivery through tomeasuring protein expression and immune response.
Target genes for mRNA therapeutics and vaccines are often discovered and validated using techniques, such as next generation sequencing (NGS). The target sequence will be selected, optimized, synthesized, and inserted into a DNA plasmid to use as a template for mRNA synthesis using in vitro transcription to produce the mRNA for further testing.
In vitro transcription uses the linearized DNA template containing the target gene, nucleotides, and enzymes to synthesize mRNA. The resulting mRNA product can be synthesized utilizing modified nucleotides or with mRNA capping and tailing to enhance protein translation, improve stability, or reduce immunogenicity as required.
The final mRNA product is isolated and purified by affinity purification using beads or a column and further prepared using chromatography and filtration as needed. After purification, the mRNA is formulated for delivery to the test model system typically using lipid nanoparticles that are made up of a number of component lipids and other materials.
Once the target mRNA has been synthesized, formulated, and delivered, measuring uptake and incorporation of the mRNA is typically done using a cell- or tissue-based system. mRNA incorporation can be measured and visualized using several techniques including RT-PCR, Northern blot, or in situ hybridization.
mRNA therapeutics or vaccines are often designed to induce production of a protein or protein fragment in target cells and patients. Measuring the production of the protein encoded by the mRNA is key to determining the success of a mRNA therapeutic candidate. During the pre-clinical phase, protein expression can be measured indirectly using techniques such as western blotting or fluorescence detection, or directly by liquid chromatography-mass spectrometry (LCMS).
T cell activation is also an important measure of the activity of an mRNA, particularly with immunotherapies, and antigen processing and presentation can be monitored using appropriate T cell gene expression microarrays.
Alternatively, many mRNA based immune therapies are designed to stimulate humoral immunity through the production of antibodies directed at the target protein encoded by the mRNA. Measuring this antibody response to the mRNA therapeutic candidate is vital information for an mRNA immunotherapeutic or vaccine. During the discovery phase, ELISA assays are a commonly used technique to track an antibody or protein response to an mRNA therapeutic candidate.
Target genes for mRNA therapeutics and vaccines are often discovered and validated using techniques, such as next generation sequencing (NGS). The target sequence will be selected, optimized, synthesized, and inserted into a DNA plasmid to use as a template for mRNA synthesis using in vitro transcription to produce the mRNA for further testing.
In vitro transcription uses the linearized DNA template containing the target gene, nucleotides, and enzymes to synthesize mRNA. The resulting mRNA product can be synthesized utilizing modified nucleotides or with mRNA capping and tailing to enhance protein translation, improve stability, or reduce immunogenicity as required.
The final mRNA product is isolated and purified by affinity purification using beads or a column and further prepared using chromatography and filtration as needed. After purification, the mRNA is formulated for delivery to the test model system typically using lipid nanoparticles that are made up of a number of component lipids and other materials.
Once the target mRNA has been synthesized, formulated, and delivered, measuring uptake and incorporation of the mRNA is typically done using a cell- or tissue-based system. mRNA incorporation can be measured and visualized using several techniques including RT-PCR, Northern blot, or in situ hybridization.
mRNA therapeutics or vaccines are often designed to induce production of a protein or protein fragment in target cells and patients. Measuring the production of the protein encoded by the mRNA is key to determining the success of a mRNA therapeutic candidate. During the pre-clinical phase, protein expression can be measured indirectly using techniques such as western blotting or fluorescence detection, or directly by liquid chromatography-mass spectrometry (LCMS).
T cell activation is also an important measure of the activity of an mRNA, particularly with immunotherapies, and antigen processing and presentation can be monitored using appropriate T cell gene expression microarrays.
Alternatively, many mRNA based immune therapies are designed to stimulate humoral immunity through the production of antibodies directed at the target protein encoded by the mRNA. Measuring this antibody response to the mRNA therapeutic candidate is vital information for an mRNA immunotherapeutic or vaccine. During the discovery phase, ELISA assays are a commonly used technique to track an antibody or protein response to an mRNA therapeutic candidate.
Dive into in vitro transcription with an experimental overview and resources to understand how mRNA is synthesized.
Discover the evolution of mRNA research and in vitro transcription, from foundational discoveries through modern-day implications.
Understand how synthetic mRNA produced via in vitro transcription has emerged as a useful tool in oncology therapeutic research.
Learn how mRNA vaccines are utilized in vivo and the role of lipid nanoparticles.
Uncover how COVID-19 vaccine development has influenced mRNA vaccine research in other therapeutic areas.
For Research Use Only. Not for use in diagnostic procedures.