[IT1200] EzRNA™ T7 高產量RNA合成試劑盒(me1Ψ-UTP),50 RXN

Every component within the IVT kit has undergone testing to confirm the absence of contaminating ribonuclease activities. Nevertheless, the creation of an RNase-free working environment and the use of RNase-free solutions are essential prerequisites for achieving successful in vitro transcription.

General recommendations to avoid RNase contamination are:

A. Maintain a separate area, dedicated pipettors and reagents for RNA work.

B. Wear gloves when handling RNA and reagents for work with RNA. Change gloves frequently.

C. Use sterile RNase-free plastic tubes and pipette tips.

D. Treat water and all solutions used for RNA purification and handling with DEPC-H2O. Add DEPC to a final concentration of 0.1% (v/v), incubate overnight at room                            temperature and autoclave.

E. Keep all kit components sealed when not in use and all tubes tightly closed during transcription reaction.

In vitro-transcribed (IVT) RNA is generally not recommended for cell transfection or in vivo studies, certain considerations need to be addressed before its direct use. 

A. RNA modifications: Some modifications, such as a 5' cap structure and a poly(A) tail, are often added to IVT RNA to enhance stability and translational efficiency. The                      absence of these modifications in IVT RNA may result in reduced expression levels and rapid degradation in cells.

B. Purity and integrity: The quality of IVT RNA is crucial for successful transfection or in vivo studies. Contaminants such as template DNA, short RNA fragments, or                              unincorporated nucleotides can affect transfection efficiency and cell viability. Therefore, it's important to purify the IVT RNA to remove these impurities.

C. Transfection reagents: The choice of transfection reagent is critical for the successful delivery of IVT RNA into cells. Not all transfection reagents are suitable for RNA                      transfection, and optimization of the transfection protocol may be necessary for specific cell types.

If the yield of the control group is normal while the yield obtained from experimental group is low, there may be quality problems in the template of the experimental group. It is recommended to try the following solutions: 

A. The DNA template may contain components that inhibit the IVT reaction. Please repurify the DNA template. The template should be RNase-free and at high concentration 

B. Determine template quantity and its integrity 

C. Extend transcription reaction time 

D. Increase template input 

If the transcription fragment is too short, the reaction will be inhibited. When the transcription length is less than 500 nt, please prolong the reaction time and increase the amount of template input. It is recommended to use 2 μg of template.
For the transcription of super-short fragments e.g. 100 nt, it is recommended to add 2 μg of template to reaction mixture for at least 6 hours, and 16 hours of overnight transcription for maximum yield.

The transcription mixture typically starts to become turbid approximately 15 minutes after setting up the reaction. This turbidity, or increase in viscosity, indicates RNA transcription occurring and eventual precipitation of RNA out of the reaction mixture.

Lithium Chloride (LiCl) precipitation is efficient in eliminating unbound NTPs and proteins.
However, if the RNA size is below 300 nt or the concentration is less than 0.1 μg/μl, effective RNA recovery becomes challenging. In such cases, consider purifying the RNA through spin column or ethanol precipitation following phenol-chloroform extraction. RNA purified using these methods is suitable for downstream applications such as cell transfection, electroporation, and microinjection experiments.

The compatibility with Cap analog depends on the specific type of the Cap analog utilized. When CleanCap® Reagent AG is employed, the RNA yield generated by the EzRNATM T7 High Yield RNA Synthesis Kit is minimally affected and thus it is compatible with EzRNATM T7 High Yield RNA Synthesis Kit.

However, when co-transcribing with conventional Cap analogs such as ARCA (anti-reverse cap analog), the RNA yield may decrease. This reduction becomes more significant with higher concentrations of ARCA. The decrease in yield is primarily attributed to the competition between ARCA and GTP (guanosine triphosphate) for incorporation into the RNA transcript, leading to incomplete transcripts and an overall reduction in RNA yield.

Thus, it is advisable not to combine the EzRNATM T7 High Yield RNA Synthesis Kit with conventional Cap analogs but instead to use CleanCap® Reagent AG or enzymatic capping method for RNA capping.

Yes, it is generally necessary to remove the DNA template after an IVT reaction, especially if the RNA product is intended for downstream applications where DNA contamination can interfere with the results or compromise the experiment's integrity.
Removing the DNA template after an IVT reaction is essential to maintain the integrity, specificity, and purity of the RNA for downstream applications. It helps ensure accurate and reliable results in molecular biology experiments.

A. DNase treatment: Add DNase I into the IVT reaction mixture to degrade any residual DNA template after IVT reaction.
        DNase I is selective in cleaving both single-stranded and double-stranded DNA while preserving the integrity of RNA.
        Subsequently, apply heat to inactivate DNase I, ensuring its inactivation and the preservation of RNA integrity.

B. Lithium Chloride (LiCl) precipitation: LiCl precipitation is a commonly used method to selectively precipitate RNA while leaving DNA and other contaminants in solution.
        However, it is important to note that LiCl precipitation may not be suitable for all RNA samples (e.g. RNA size < 300 nt), and alternative purification methods may be preferred          based on specific requirements.

The use of modified nucleotides in IVT RNA synthesis can improve the stability, translational efficiency, and reduce immunogenicity of RNA molecules, making them more suitable for various experimental and therapeutic applications.

A. Enhanced stability: Modified nucleotides can enhance the stability of the resulting RNA molecules. For instance, 2'-O-methylated nucleotides can increase RNA stability by              protecting against enzymatic degradation by nucleases.

B. Improved translation efficiency: Certain modifications, such as pseudouridine (Ψ), can enhance translation efficiency by facilitating ribosome binding and elongation during              protein synthesis.

C. Reduced immunogenicity: Unmodified RNA molecules may elicit an immune response when introduced into cells or organisms. Modified nucleotides, such as N1-methyl                  pseudouridine, can reduce the immunogenicity of IVT RNA by minimizing recognition by cellular innate immune sensors.

For in vitro-transcribed RNA, the poly(A) tail can be encoded in the DNA template by using an appropriately tailed PCR primer, or enzymatically added to the RNA by Poly(A) Polymerase in a separate step following IVT reaction. 

To assess RNA concentration most conveniently, utilize ultraviolet light absorption at a wavelength of 260 nm. Dilute a portion of the reaction at a 1:300 ratio to achieve an absorbance reading within the linear range of a spectrophotometer.

For single-stranded RNA, when A260 = 1, RNA concentration is 40 μg/mL. The RNA yield can be determined using the formula: A260 × 300 (dilution factor) × 40 = __ μg/mL RNA.

It's important to note that unincorporated nucleotides and template DNA in the mixture may interfere with the reading. Therefore, for precise quantification, it is advisable to remove the template and nucleotides from the transcription mixture.