Search Thermo Fisher Scientific
- Order Status
- Quick Order
-
Don't have an account ? Create Account
Search Thermo Fisher Scientific
Topoisomerase I from Vaccinia virus binds to duplex DNA at specific sites and cleaves the phosphodiester backbone after 5´ -CCCTT in one strand (Shuman, 1991). The energy from the broken phosphodiester backbone is conserved by formation of a covalent bond between the 3´ phosphate of the cleaved strand and a tyrosyl residue (Tyr-274) of topoisomerase I. The phospho-tyrosyl bond between the DNA and enzyme can subsequently be attacked by the 5´ hydroxyl of the original cleaved strand, reversing the reaction and releasing topoisomerase (Shuman, 1994). TOPO Cloning exploits this reaction to efficiently clone PCR products (see diagram below).
The design of the PCR primers to amplify your gene of interest is critical for expression. Depending on the pET TOPO vector you are using, consider the following when designing your PCR primers:
To enable directional cloning, the forward PCR primer must contain the sequence, CACC, at the 5´ end of the primer. The 4 nucleotides, CACC, base pair with the overhang sequence, GTGG, in each pET TOPO vector.
For example, below is the DNA sequence of the N-terminus of a theoretical protein and the proposed sequence for your forward PCR primer:
DNA sequence: 5´ -ATG GGA TCT GAT AAA
Proposed Forward PCR primer: 5´ -C ACC ATG GGA TCT GAT AAA
In general, design the reverse PCR primer to allow you to clone your PCR product in frame with any C-terminal tag, if desired. To ensure that your PCR product clones directionally with high efficiency, the reverse PCR primer must not be complementary to the overhang sequence GTGG at the 5´ end. A one base pair mismatch can reduce the directional cloning efficiency from 90% to 75%, and may increase the chances of your ORF cloning in the opposite orientation. We have not observed evidence of PCR products cloning in the opposite orientation from a two base pair mismatch, but this has not been tested thoroughly.
Example: Below is the sequence of the C-terminus of a theoretical protein. You want to clone in frame with the C-terminal tag. The stop codon is underlined.
DNA sequence: AAG TCG GAG CAC TCG ACG ACGGTG tag-3´
One solution is to design the reverse PCR primer to start with the codon just up-stream of the stop codon, but the last two codons contain GTGG (underlined below), which is identical to the overhang sequence. As a result, the reverse primer will be complementary to the overhang sequence, increasing the probability that the PCR product will clone in the opposite orientation. You want to avoid this situation.
DNA sequence: AAG TCG GAG CAC TCG ACG ACG GTG tag-3´
Proposed Reverse PCR primer sequence: TG AGC TGC TGC CAC-5´
Another solution is to design the reverse primer so that it hybridizes just down-stream of the stop codon, but still includes the C-terminus of the ORF. Note that you will need to replace the stop codon with a codon for an innocuous amino acid such as glycine or alanine.
The example below uses a theoretical protein and is for illustration purposes only. In this case, PCR primers are designed to allow cloning of the PCR product into pET101/D-TOPO. In this example, the N-terminus of the protein is encoded by:
5´ -atggcccccccgaccgatgtcagcctgggggacgaa…
Invitrogen Platinum SuperFi DNA Polymerase is a proofreading DNA polymerase that combines exceptional fidelity with trusted Platinum hot-start technology. Featuring >100x the fidelity of Taq polymerase, Platinum SuperFi DNA Polymerase is ideally suited for cloning, mutagenesis, and other applications that benefit from sequence accuracy.
Benefits of Platinum SuperFi DNA Polymerase include:
Platinum SuperFi DNA Polymerase is engineered with a DNA-binding domain, resulting in high processivity and increased resistance to PCR inhibitors. This feature also enables fast-cycling protocols and amplification of long targets. The Platinum hot-start technology is based on proprietary antibodies that inhibit enzyme activity until the initial PCR denaturation step, preventing nonspecific amplification and primer degradation.
Platinum SuperFi DNA Polymerase is supplied with a separate vial of Invitrogen SuperFi GC Enhancer designed for GC-rich templates (>65% GC).
The following procedure is suggested as a starting point when using Platinum SuperFi DNA Polymerase in PCR amplification.
1 Important!Always use the Tm calculator on our website at thermofisher.com/tmcalculator to calculate the Tm of your primers and the recommended annealing temperature.
Note: Consider the volumes for all components listed in steps 2 and 4 to determine the correct amount of water required to reach your final reaction volume.
Component | 50-μL rxn | Final conc. |
---|---|---|
Water, nuclease-free | to 50 μL | |
5X SuperFi Buffer1 | 10 μL | 1X |
10 mM dNTP mix | 1 μL | 0.2 mM each |
5X Super GC Enhancer (optional) 2 | 10 μL | 1X |
Platinum SuperFi DNA Polymerase | 0.5 μL | 0.02 U/μL |
Component | 50-μL rxn | Final conc. |
---|---|---|
10 μM forward primer | 2.5 μL | 0.5 μM |
10 μM reverse primer | 2.5 μL | 0.5 μM |
Template DNA1 | varies | varies |
1 Optimal amount of low complexity DNA (plasmid, phage, BAC DNA) is 1 pg–10 ng per 50 μL reaction, but it can be varied from 0.1 pg to 50 ng per 50 μL reaction. Optimal amount of genomic DNA is 5–50 ng per 50 μL reaction, but it can be varied from 0.1 ng to 250 ng per 50 μL reaction.
Smearing, multiple banding, primer-dimer artifacts, or large PCR products (>3 kb) may necessitate gel purification. If you intend to purify your PCR product, be extremely careful to remove all sources of nuclease contamination. There are many protocols to isolate DNA fragments or remove oligonucleotides. Refer to Current Protocols in Molecular Biology, Unit 2.6 (Ausubel et al., 1994) for the most common protocols. Three simple protocols are provided below. Cloning efficiency may decrease with purification of the PCR product. You may wish to optimize your PCR to produce a single band.
The S.N.A.P. Gel Purification Kit allows you to rapidly purify PCR products from regular agarose gels.
An even easier method is to simply cut out the gel slice containing your PCR product, place it on top of the S.N.A.P. column bed, and centrifuge at full speed for 10 seconds. Use 1-2 µl of the flow-through in the TOPO™ Cloning reaction. Be sure to make the gel slice as small as possible for best results.
If you prefer to use low-melt agarose, use the procedure below. Note that gel purification will result in dilution of your PCR product and a potential loss of cloning efficiency.
The cloning efficiency may decrease with purification of the PCR product. You may wish to optimize your PCR to produce a single band.
Once you have produced the desired PCR product, you are ready to TOPOClone it into the pET TOPOvector and transform the recombinant vector into One Shot TOP10 E. coli. You should have everything you need set up and ready to use to ensure that you obtain the best possible results. We suggest that you read the this section and the next section entitled Transforming Chemically Competent Cells before beginning. If this is the first time you have TOPO Cloned, perform the control reactions (see Performing Control Reactions) in parallel with your samples.
When performing directional TOPO Cloning, we have found that the molar ratio of PCR product:TOPO vector used in the reaction is critical to its success. To obtain the highest TOPO Cloning efficiency, use a 0.5:1 to 2:1 molar ratio of PCR product:TOPO vector. Note that the TOPO Cloning efficiency decreases significantly if the ratio of PCR product: TOP vector is <0.1:1 or >5:1 These results are generally obtained if too little PCR product is used (i.e. PCR product is too dilute) or if too much PCR product is used in the TOPO Cloning reaction. If you have quantitated the yield of your PCR product, you may need to adjust the concentration of your PCR product before proceeding to TOPO Cloning.
You will perform TOPO Cloning in a reaction buffer containing salt (i.e. using the stock salt solution provided in the kit). Note that the amount of salt added to the TOPO Cloning reaction varies depending on whether you plan to transform chemically competent cells (provided) or electrocompetent cells.
Use the procedure below to perform the TOPO Cloning reaction. Set up the TOPO Cloning reaction depending on whether you plan to transform chemically competent E. coli or electrocompetent E. coli. Reminder: For optimal results, be sure to use a 0.5:1 to 2:1 molar ratio of PCR product:TOPO vector in your TOPO Cloning reaction.
Reagents* | Chemically Competent E. coli | Electrocompetent E. coli |
Fresh PCR product
|
0.5 to 4 µl
|
0.5 to 4 µl
|
Salt Solution
|
1 µl
|
--
|
Dilute Salt Solution (1:4)
|
--
|
1 µl
|
Sterile Water
|
add to a final volume of 5 µl
|
add to a final volume of 5 µl
|
TOPO vector
|
1 µl
|
1 µl
|
Total Volume
|
6 µl
|
6 µl
|
*Store all reagents at -20°C when finished. Salt solution and water can be stored at room temperature or +4°C.
For Research Use Only. Not for use in diagnostic procedures.