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View additional product information for CloneMiner™ II cDNA Library Construction Kit - FAQs (A11180)
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The SuperScript Full length cDNA Library Construction Kit has been discontinued. The alternative is the CloneMiner II cDNA Library Construction Kit, Cat. No. A11180.
Gateway entry clone cDNA libraries are ready to transfer into suitable destination vectors for gene expression. You do not have to worry about restriction enzyme digestion of cDNA (which can decrease the insert size,) or vector prior to cloning.
We would recommend using the CloneMiner cDNA Library Construction Kit (Cat. No. A11180) for construction of high-quality Gateway cloning-compatible cDNA libraries without the use of restriction enzyme cloning. This system uses highly efficient recombinational cloning, resulting in a higher number of primary clones compared to standard cDNA library construction methods.
There is no theoretical limit to insert size for a BP reaction with a pDONR vector. Maximum size tested in-house is 12 kb. TOPO vectors are more sensitive to insert size and 3-5 kb is the upper limit for decent cloning efficiency.
After generating your attB-PCR product, we recommend purifying it to remove PCR buffer, unincorporated dNTPs, attB primers, and any attB primer-dimers. Primers and primer-dimers can recombine efficiently with the Donor vector in the BP reaction and may increase background after transformation into E. coli, whereas leftover PCR buffer may inhibit the BP reaction. Standard PCR product purification protocols using phenol/chloroform extraction followed by ammonium acetate and ethanol or isopropanol precipitation are not recommended for purification of the attB-PCR product as these protocols generally have exclusion limits of less than 100 bp and do not efficiently remove large primer-dimer products. We recommend a PEG purification protocol (see page 17 of the Gateway Technology with Clonase II manual). If you use the above protocol and your attB-PCR product is still not suitably purified, you may further gel-purify the product. We recommend using the PureLink Quick Gel Extraction kit.
Check the genotype of the cell strain you are using. Our Gateway destination vectors typically contain a ccdB cassette, which, if uninterrupted, will inhibit E. coli growth. Therefore, un-cloned vectors should be propagated in a ccdB survival cell strain, such as our ccdB Survival 2 T1R competent cells.
LR Clonase II Plus contains an optimized formulation of recombination enzymes for use in MultiSite Gateway LR reactions. LR Clonase and LR Clonase II enzyme mixes are not recommended for MultiSite Gateway LR recombination reactions, but LR Clonase II Plus is compatible with both multi-site and single-site LR recombination reactions.
When the LR reaction is complete, the reaction is stopped with Proteinase K and transformed into E. coli resulting in an expression clone containing a gene of interest. A typical LR reaction followed by Proteinase K treatment yields about 35,000 to 150,000 colonies per 20ul reaction. Without the Proteinase K treatment, up to a 10 fold reduction in the number of colonies can be observed. Despite this reduction, there are often still enough colonies containing the gene of interest to proceed with your experiment, so the Proteinase K step can be left out after the LR reaction is complete if necessary.
The following protocol can be used to prepare ssDNA from DH12S or DH5aF', DH5aF'IQ, DH11S cells (this strain not currently offered for sale). Use a stock of the helper phage M13KO7 (1) that is of known titer. For convenience, DH12S cells are supplied with M13KO7 helper phage. DH12S cells are both endA positive, so single stranded DNA isolated from these strains tend to be less contaminated with double stranded rf DNA.
Small-Scale Preparation of ss Phagemid DNA:
1. Pick a single colony of cells containing phagemid DNA and resuspend in 2 mL TBG (1.2% tryptone, 2.4% yeast extract 0.4% glycerol, 17 mM KH2PO4 and 55 mM KH2PO4 and 20 mM glucose) containing 100 µg/mL ampicillin in a 15 mL tube.
2. Immediately add 10 µL M13KO7 helper phage stock at 10E11 pfu/mL.
3. Incubate cells at 37 degrees C with vigorous agitation (275 rpm) for 2 hrs.
4. Add kanamycin to a final concentration of 75 µg/mL and incubate cells at 37 degrees C with vigorous agitation (275 rpm) for 18 to 24 hrs.
5. Transfer 1.5 mL of culture to a sterile microcentrifuge tube and pellet cells by centrifuging at 14,000 x g for 10 min at 4 degrees C.
6. Transfer supernatant to fresh microcentrifuge tube and repeat the centrifugation.
7. Transfer 1.2 mL supernatant to a fresh microcentrifuge tube and add 300 µL of 2.5 M NaCl in 40% PEG 4000.
8. Vortex and incubate on ice for 15 min.
9. Centrifuge at 14,000 x g for 15 min at 4 degrees C.
10. Resuspend the pellet in 50 µL TE and phenol extract to remove the viral coat.
11. Use 10 µL of the final 50 µL volume for gel analysis.
This protocol yields 0.5 to 1 µg ss phagemid DNA.
Large-Scale Preparation of ss Phagemid DNA:
1. Resuspend a single colony in 5 mL of TB or LB broth containing 100 µg/mL ampicillin in a 15-mL tube.
2. Shake at 37 degrees C and 275 rpm overnight.
3. Add 100 µL of the overnight culture to 200 mL LB broth and 100 µg/mL ampicillin in a 1 L flask. Incubate at 37 degrees C with shaking (275 rpm) for 3 hrs.
4. Add 200 µL of M13KO7 helper phage (1 x 10E11 pfu/mL) to the culture and continue to incubate for 2 hrs.
5. Add 1.5 mL of 1% (w/v) kanamycin to the cells for a final concentration of 75 µg/mL. Incubate the infected cells for an additional 18 to 24 h at 37 degrees C.
6. Centrifuge this culture at 16,000 x g for 15 min at 4 degrees C .
7. Filter the supernatant through a 0.2 µm sterile filter into an autoclaved centrifuge bottle. Add 40 µL of DNase I (50 units/µL) and incubate at room temperature for 3 hrs. This step should remove any residual ds plasmid DNA contamination.
8. Transfer 100 mL of the supernatant to another centrifuge bottle. Add 25 mL of 2.5 M NaCl in 40% PEG 4000 to each of the centrifuge bottles containing the supernatant.
9. Vortex the mixture, incubate on ice for 1 h, and centrifuge at 16,000 x g for 20 min at 4 degrees C.
10. Carefully discard the supernatant. To fully drain off the remaining solution from the pellets, place the bottles on an angle, with the pellet side facing up for 10 to 15 min. Remove the solution with a sterile Pasteur pipet.
11. Resuspend the pellets in 2 mL of TE buffer. Add 10 µL of proteinase K solution (20 mg/mL), 20 µL of 10% SDS, and incubate this mixture at 45 degrees C for 1 hr.
12. Transfer the digested mixture to three microcentrifuge tubes and extract four times with an equal volume of phenol:chloroform: isoamyl alcohol (25:24:1), precipitate with ethanol, and dissolve in 100 µL TE buffer.
13. Freeze the solubilized DNA at -20 degrees C for 1 hr and centrifuge in a microcentrifuge at 14,000 x g for 15 min at 4 degrees C.
14. Transfer the supernatant containing the ss plasmid DNA to a fresh tube and discard the polysaccharide pellet. Store the ssDNA at 4 degrees C.
15. Determine the DNA concentration (OD260).
This protocol yields ~100 to 200 µg ss phagemid DNA.
(1) Vieira, J. and Messing, J. (1987) Methods in Enzymology 153, 3.
Lawn cells for M13 infection must be made with an E. coli strain containing the F' episome. Some of our competent cells that may be used include: DH5aF'IQ, INValphaF', TOP10F', OmniMAX2, Stbl4, or DH12S cells.
To make a glycerol stock of lawn cells:
1) Streak cells on an LB plate and incubate overnight at 37C.
2) Pick a single colony from the plate into 50 ml LB or S.O.B. medium and incubate the culture at 37C until the OD550 reaches 2.0.
3) Centrifuge the cells in a clinical centrifuge at 3,000 x g for 10 min at 4C.
4) Resuspend the pellet in 5 ml 60% S.O.B. and 40% glycerol.
5) Aliquot the cells and freeze them in a dry ice/ethanol bath. Store the cells at -70C.
LB Medium (per liter):
- 10 g Tryptone (SELECT Peptone 140)
- 5 g Yeast Extract (SELECT Yeast Extract)
- 10 g NaCl
Add Distilled Water to a final volume of 1 L. Stir to dissolve, and autoclave.
S.O.B. Medium (per liter):
- 20 g Tryptone (SELECT Peptone 140)
- 5 g Yeast Extract (SELECT Yeast Extract)
- 10 ml 1 M NaCl
- 2.5 ml 1 M KCl
- 10 ml 1 M MgCl2
- 10 ml 1 M MgSO4
Add tryptone, yeast extract, NaCl, and KCl to a flask or bottle, and add Distilled Water to a final volume of 1 L (~980 ml). Stir to dissolve, autoclave, and cool to room temperature. Then add Mg++ stock solutions (1 M MgCl2/6H2O and 1 M MgSO4/7H2O, filter sterilized). Mg++ solutions should not be added before autoclaving, as this will likely result in precipitation.
Ethanol precipitation is frequently used for concentration of DNA solutions and for removal of protein, salt, and unincorporated nucleotides. The two most common protocols use either 0.3 M sodium acetate (0.1 volume of 3 M) or 2.5 M ammonium acetate (0.5 volume of 7.5 M), along with 2 to 2.5 volumes of ethanol. Studies at Thermo Fisher Scientific (1, 2) have shown these two salts to be equally effective for recovery of small amounts of DNA from small volumes and for removal of unincorporated nucleotides from labeling reactions.
DNA was found to precipitate readily with room temperature ethanol and room temperature centrifugation. For DNA concentrations >0.1 µg/mL, no incubation period is required. For improved recovery of DNA from dilute solutions (10 ng/mL), overnight incubation in the ethanol and extended (30 min) centrifugation is recommended. Addition of ammonium acetate to 2.5 M (without ethanol) has also been shown to be effective in precipitating proteins while leaving the DNA in solution (2).
1. Zeugin, J.A. and Hartley, J.L. (1985) FOCUS 7:4, 1.
2. Crouse, J. and Amorese, D. (1987) FOCUS 9:2, 3.
Plasmid libraries may be amplified using several different methods. Growth in liquid culture will frequently result in skewed representation of clones due to differential growth characteristics of individual clones. To minimize these representational biases, we recommend semi-solid amplification. With this method, colonies are grown in 2X LB broth and 0.3% agarose in suspension, facilitating equal growth of all clones and avoiding disproportionate amplification.
Alternatively, amplification of plasmid libraries may be done on selective agar plates, as described below. Libraries containing expression vector plasmids such as pSPORT or pCMV SPORT should be grown under noninduced conditions (no lactose, no IPTG). The lac repressor gene encoded on the pSPORT plasmid is sufficient to prevent expression of the recombinant genes cloned into the multiple cloning site. Repression of expression is necessary to ensure the amplification of clones whose gene products may be harmful to survival of the E. coli host.
Recommended protocol for Library Amplification on Plates:
1. After titering the original library, plate the cells at a density of ~1 x 10E4 CFU per 100 mm plate or ~0.5 x 10E5 CFU per 150 mm plate. Use selective media containing the appropriate antibiotic.
2. Grow at 37°C until a thick lawn is visible (~6 to 12 h).
3. Add 5 ml per 100 mm plate or 15 ml per 150 mm plate of S.O.C. medium or LB broth.
4. Gently coax the bacterial lawn into the broth with a cell scraper (or a glass slide).
5. Collect the suspension and repeat steps 3 and 4 once more. Pool the broths, then incubate at 37°C for no longer than 1 h with constant swirling.
6a. If the bacterial suspension is highly dense, add glycerol to a concentration of 15% to 50%; aliquot the cells into cryovials; and immediately store them at -70°C.
6b. If the bacterial solution is too dilute, centrifuge at 7,000 x g for 10 min and resuspend in a smaller volume of 15% to 50% glycerol/media and freeze.
7. For use, thaw the cryovials and plate dilutions onto selective media.
NOTE:
-The viability of E. coli stored at -70°C will not change substantially for years, unless thawed and refrozen.
In most cases, there will not be enough pENTR vector DNA present to go directly from TOPO cloning into an LR reaction. You need between 100-300 ng of pENTR vector for an efficient LR reaction, and miniprep of a colony from the TOPO transformation is necessary to obtain that much DNA. However, if you want to try it, here are some recommendations for attempting to go straight into LR reactions from the TOPO reaction using pENTR/D, or SD TOPO, or pCR8/GW/TOPO vectors:
1. Heat inactivate the topoisomerase after the TOPO cloning reaction by incubating the reaction at 85 degrees C for 15 minutes.
2. Use the entire reaction (6 µL) in the LR clonase reaction. No purification steps are necessary.
3. Divide the completed LR reaction into 4 tubes and carry out transformations with each tube. You cannot transform entire 20 µL reaction in one transformation, and we have not tried ethanol precipitation and then a single transformation.
When attempting this protocol, we observed very low efficiencies (~10 colonies/plate). So just be aware that while technically possible, going directly into an LR reaction from a TOPO reaction is very inefficient and will result in a very low colony number, if any at all.
To have an N-terminal tag, the gene of interest must be in the correct reading frame when using non-TOPO adapted Gateway entry vectors. All TOPO adapted Gateway Entry vectors will automatically put the insert into the correct reading frame, and to add the N-terminal tag you simply recombine with a destination vector that has N-terminal tag.
To attach a C-terminal tag to your gene of interest, the insert must lack its stop codon, and be in the correct reading frame for compatibility with our C-terminal tagged destination vectors. Again, TOPO adapted Gateway Entry vectors will automatically put the insert into the correct reading frame. If you do not want the C-terminal tag to be expressed, simply include a stop codon at the end of the insert that is in frame with the initial ATG.
Generally, you need to choose a destination vector before you design and clone your insert into the Entry vector. This will determine whether you need to include an initiating ATG or stop codon with your insert.
No, not directly. The attB-PCR product must first be cloned, via a BP Clonase reaction, into a pDONR vector which creates an "Entry Clone" with attL sites. This clone can then be recombined, via an LR Clonase reaction, with a Destination vector containing attR sites. However, It is possible to perform both of these reactions in one step using the "One-Tube Protocol" described in the manual entitled "Gateway Technology with Clonase II".
Yes, this can be done using the Multisite Gateway Technology. MultiSite Gateway Pro Technology enables you to efficiently and conveniently assemble multiple DNA fragments - including genes of interest, promoters, and IRES sequences - in the desired order and orientation into a Gateway Expression vector. Using specifically designed att sites for recombinational cloning, you can clone two, three, or four DNA fragments into any Gateway Destination vector containing attR1 and attR2 sites. The resulting expression clone is ready for downstream expression and analysis applications.
For the BP reaction, approximately 5-10% of the starting material is converted into product. For the LR reaction, approximately 30% of the starting material is converted into product.
The core region of the att sites contains the recognition sequence for the restriction enzyme BsrGI. Provided there are no BsrGI sites in the insert, this enzyme can be used to excise the full gene from most Gateway plasmids. The BsrGI recognition site is 5'-TGTACA and is found in both att sites flanking the insertion site.
If a different restriction site is desired, the appropriate sequence should be incorporated into your insert by PCR.
We do have an alternative method called the "attB Adapter PCR" Protocol in which you make your gene specific primer with only 12 additional attB bases and use attB universal adapter primers. This protocol allows for shorter primers to amplify attB-PCR products by utilizing four primers instead of the usual two in a PCR reaction. You can find the sequence of these primers in the protocol on page 45 of the "Gateway Technology with Clonase II" manual.
There is a protocol in which all 4 primers mentioned above are in a single PCR reaction. You can find this protocol at in the following article: Quest vol. 1, Issue 2, 2004. https://www.thermofisher.com/us/en/home/references/newsletters-and-journals/quest-archive.reg.in.html. The best ratio of the first gene-specific and the second attB primers was 1:10.
We do not offer pre-made primers, but we can recommend the following sequences that can be ordered as custom primers for sequencing of pDONR201:
Forward primer, proximal to attL1: 5'- TCGCGTTAACGCTAGCATGGATCTC
Reverse primer, proximal to attL2: 5'-GTAACATCAGAGATTTTGAGACAC
1. Yeast two-hybrid protein-protein interaction studies Walhout AJ, Sordella R, Lu X, Hartley JL, Temple GF, Brasch MA, Thierry-Mieg N, Vidal M.
2. Protein Interaction Mapping in C. elegans Using Proteins Involved in Vulval Development. Science Jan 7th 2000; 287(5450), 116-122 Davy, A. et al.
3. A protein-protein interaction map of the Caenorhabditis elegans 26S proteosome. EMBO Reports (2001) 2 (9), p. 821-828. Walhout, A.J.M. and Vidal, M. (2001).
4. High-throughput Yeast Two-Hybrid Assays for Large-Scale Protein Interaction mapping. Methods: A Companion to Methods in Enzymology 24(3), pp.297-306
5. Large Scale Analysis of Protein Complexes Gavin, AC et al. Functional Organization of the Yeast Proteome by Systematic Analysis of Protein Complexes. Nature Jan 10th 2002, 415, p. 141-147.
6. Systematic subcellular localisation of proteins Simpson, J.C., Wellenreuther, R., Poustka, A., Pepperkok, R. and Wiemann, S.
7. Systematic subcellular localization of novel proteins identified by large-scale cDNA sequencing. EMBO Reports (2000) 1(3), pp. 287-292.
8. Protein-over expression and crystallography Evdokimov, A.G., Anderson, D.E., Routzahn, K.M. & Waugh, D.S.
9. Overproduction, purification, crystallization and preliminary X-ray diffraction analysis of YopM, an essential virulence factor extruded by the plague bacterium Yersinia pestis. Acta Crystallography (2000) D56, 1676-1679.
10. Evdokimov, et al. Structure of the N-terminal domain of Yersinia pestis YopH at 2.0 A resolution. Acta Crystallographica D57, 793-799 (2001).
11. Lao, G. et al. Overexpression of Trehalose Synthase and Accumulation of Intracellular Trehalose in 293H and 293FTetR:Hyg Cells. Cryobiology 43(2):106-113 (2001).
12. High-throughput cloning and expression Albertha J. M. Walhout, Gary F. Temple, Michael A. Brasch, James L. Hartley, Monique A. Lorson, Sander Van Den Huevel, and Marc Vidal.
13. Gateway Recombinational Cloning: Application to the Cloning of Large Numbers of Open Reading Frames or ORFeomes. Methods in Enzymology, Vol. 328, 575-592.
14. Wiemann, S. et.al., Toward a Catalog of Human Genes and Proteins: Sequencing and Analysis of 500 Novel Complete Protein Coding Human cDNAs, Genome Research (March 2001) Vol. 11, Issue 3, pp.422-435
15. Reviewed in NATURE: Free Access to cDNA provides impetus to gene function work. 15 march 2001, p. 289. Generating directional cDNA libraries using recombination
16. Osamu Ohara and Gary F. Temple. Directional cDNA library construction assisted by the in vitro recombination reaction. Nucleic Acids Research 2001, Vol. 29, no. 4. RNA interference (RNAi)
17. Varsha Wesley, S. et al. Construct design for efficient, effective and highthroughput gene silencing in plants. The Plant Journal 27(6), 581-590 (2001). Generation of retroviral constructs
18. Loftus S K et al. Generation of RCAS vectors useful for functional genomic analyses. DNA Res 31;8(5):221 (2001).
19. James L. Hartley, Gary F. Temple and Michael A. Brasch. DNA Cloning Using In Vitro Site-Specific Recombination. Genome Research (2000) 10(11), pp. 1788-1795.
20. Reboul et al. Open-reading frame sequence tags (OSTs) support the existence of at least 17,300 genes in C. elegans. Nature Genetics 27(3):332-226 (2001).
21. Kneidinger, B. et al. Identification of two GDP-6-deoxy-D-lyxo-4-hexulose reductase synthesizing GDP-D-rhamnose in Aneurinibacillus thermoaerophilus L420-91T*. JBC 276(8) (2001).
The attP1 sequence (pDONR) is:
AATAATGATT TTATTTTGAC TGATAGTGAC CTGTTCGTTG CAACAAATTG ATGAGCAATGCTTTTTTAT AATGCCAACT TTGTACAAAA AAGC[TGAACG AGAAACGTAA AATGATATAA ATATCAATAT ATTAAATTAG ATTTTGCATA AAAAACAGACTA CATAATACTG TAAAACACAA CATATCCAGT CACTATGAAT CAACTACTTA GATGGTATTA GTGACCTGTA]
The region within brackets is where the site is "cut" and replaced by the attB1-fragment sequence to make an attL1 site. The sequence GTACAAA is the overlap sequence present in all att1 sites and is always "cut" right before the first G.
The overlap sequence in attP2 sites is CTTGTAC and cut before C. This is attP2:
ACAGGTCACT AATACCATCT AAGTAGTTGA TTCATAGTGA CTGGATATGT TGTGTTTTAC AGTATTATGT AGTCTGTTTT TTATGCAAAA TCTAATTTAA TATATTGATA TTTATATCAT TTTACGTTTC TCGTTCAGCT TTCTTGTACA AAGTTGGCAT TATAAGAAAG CATTGCTTAT AATTTGTTG CAACGAACAG GTCACTATCA GTCAAAATAA AATCATTATT
So, attL1 (Entry Clone) should be:
A ATAATGATTT TATTTTGACT GATAGTGACC TGTTCGTTGC AACAAATTGA TGAGCAATGC TTTTTTATAA TGCCAACT TT G TAC AAA AAA GC[A GGC T]NN NNN
attL2 (Entry Clone) should be:
NNN N[AC C]CA GCT TT CTTGTACA AAGTTGGCAT TATAAGAAAG CATTGCTTAT CAATTTGTTG CAACGAACAG GTCACTATCA GTCAAAATAA AATCATTATT
The sequence in brackets comes from attB, and N is your gene-specific sequence.
Note: When creating an Entry Clone through the BP reaction and a PCR product, the vector backbone is not the same as Gateway Entry vectors. The backbone in the case of PCR BP cloning is pDONR201.
There is no size restriction on the PCR fragments if they are cloned into a pDONR vector. The upper limit for efficient cloning into a TOPO adapted Gateway Entry vector is approximately 5 kb. A Gateway recombination reaction can occur between DNA fragments that are as large as 150 kb.
Destination vectors that contain N-terminal fusion partners will express proteins that contain amino acids contributed from the attB1 site, which is 25 bases long. This means that in addition to any tag (6x His and/or antibody epitope tag), the N-terminus of an expressed protein will contain an additional 9 amino acids from the attB1 sequence - the typical amino acid sequence is Thr-Ser-Leu-Tyr-Lys-Lys-Ala-Gly-nnn, where nnn will depend on the codon sequence of the insert.
Effects on protein function: A researcher (Simpson et al. EMBO Reports 11(31):287-292, 2000) demonstrated that GFP fusions (N- terminal and C-terminal) localized to the proper intracellular compartment. The expression constructs were generated using Gateway cloning, so the recombinant protein contained the attB1 or attB2 amino acid sequence. The localization function of the cloned recombinant proteins was preserved.
Effects on expression: We have seen no effect of the attB sites on expression levels in E. coli, insect and mammalian cells. The gus gene was cloned into bacterial expression vectors (for native and N-terminal fusion protein expression) using standard cloning techniques and expressed in bacteria. Gus was also cloned into Gateway Destination vectors (for native and N-terminal fusion expression) and expressed. When protein expression is compared, there was no difference in the amount of protein produced. This demonstrates that for this particular case, the attB sites do not interfere with transcription or translation.
Effects on solubility: A researcher at the NCI has shown that Maltose Binding Protein fusions constructed with Gateway Cloning were soluble. The fusion proteins expressed had the attB amino acid sequence between the Maltose Binding Protein and the cloned protein. It is possible that some proteins containing the attB sequence could remain insoluble when expressed in E.coli.
Effects on folding: Two Hybrids screens show the same interacters identified with and without the attB sequence. Presumably correct protein folding would be required for protein-protein interactions to take place. It is possible that some proteins containing the attB sequence may not fold correctly.
Since the attB sequences are on the 5' end of oligos, they will not anneal to the target template in the first round of PCR. Sometimes the PCR product is more specific with the attB primers, probably due to the longer annealing sequence (all of attB plus gene specific sequence) after the first round of amplification. Generally there is no need to change PCR reaction conditions when primers have the additional attB sequence
No, this is not really feasible due to the fact that the attL sequence is approximately 100 bp, which is too long for efficient oligo synthesis. Our own maximum sequence length for ordering custom primers is 100 nucleotides. In contrast, the attB sequences are only 25 bp long, which is a very reasonable length for adding onto the 5' end of gene-specific PCR primers.
Vector information can be found in the product manuals or directly on our web site by entering the catalog number of the product in the search box. The vector map, cloning site diagram, and sequence information will be linked to the product page.
The Gateway nomenclature is consistent with lambda nomenclature, but we use numbers to differentiate between modified versions of the att sites (attB1, attB2, attP1, attP2, and so on). We have introduced mutations in the att sites to provide specificity and directionality to the recombination reaction. For example, attB1 will only recombine with attP1 and not with attP2.
The first step is to create an Entry clone for your gene of interest. We have 3 options to do this: The first is by BP recombination reaction using the PCR Cloning System with Gateway Technology. This is recommended for cloning large (>5 kb) PCR products. We also have Gateway compatible TOPO Cloning vectors such as pCR8/GW/TOPO and pENTR/D-TOPO. The final option is to use restriction enzymes to clone into a pENTR Dual Selection vector.
The gene of interest must be flanked by the appropriate att sites, either attL (100 bp) in an Entry clone or attB (25 bp) in a PCR product. For Entry clones, everything between the attL sites will be shuttled into the Gateway destination vector containing attR sites, and a PCR product flanked by attB sites must be shuttled into an attP-containing donor vector such as pDONR221.
The location of translation initiation sites, stop codons, or fusion tags for expression must be considered in your initial cloning design. For example, if your destination vector contains an N-terminal tag but does not have a C-terminal tag, the vector should already contain the appropriate translation start site but the stop codon should be included in your insert.
Yes, increasing the incubation time from 1 hour to 4 hours will generally increase colony numbers 2-3 fold. An overnight incubation at room temperature will typically increase colony yield by 5-10 fold.
BP Clonase II and LR Clonase II can be freeze/thawed at least 10 times without significant loss of activity. However, you may still want to aliquot the enzymes to keep freeze/thaw variability to a minimum.
These enzymes are more stable than the original BP and LR Clonase and can be stored at -20 degrees C for 6 months.
Mini-prep (alkaline lysis) DNA preparations work well in Gateway cloning reactions. It is important that the procedure remove contaminating RNA for accurate quantification. Plasmid DNA purified with our S.N.A.P. nucleic acid purification kits, ChargeSwitch kits, or PureLink kits are recommended.
A simple way to express a protein with a leader sequence is to have the leader sequence encoded in the destination vector. The other option is to have the leader sequence subcloned into the entry vector using restriction enzymes, or incorporate the leader sequence into the forward PCR primer when cloning a PCR product into the entry vector. Please see Esposito et al. (2005), Prot. Exp. & Purif. 40, 424-428 for an example of how a partial leader sequence for secretion was incorporated into an entry vector.
This depends on whether you are expressing a fusion or a native protein in the Gateway destination vector. For an N-terminal fusion protein the ATG will be given by the destination vector and it will be upstream of the attB1 site. For a C-terminal fusion protein or a native protein, the ATG should be provided by your gene of interest, and it will be downstream of the attB1 site.
The Gateway attB sites are derived from the bacteriophage lambda site-specific recombination, but are modified to remove stop codons and reduce secondary structure. The core regions have also been modified for specificity (i.e., attB1 will recombine with attP1 but not with attP2).
Expression experiments have shown that the extra amino acids contributed by the attB site to a fusion protein will most likely have no effect on protein expression levels or stability. In addition, they do not appear to have any effect on two-hybrid interactions in yeast. However, as is true with the addition of any extra sequences that result from tags, the possible effects will be protein-dependent.
No, attB primers are highly specific under standard PCR conditions. We have amplified from RNA (RT-PCR), cDNA libraries, genomic DNA, and plasmid templates without any specificity problems.
The smallest size we have recombined is a 70 bp piece of DNA located between the att sites. Very small pieces are difficult to clone since they negatively influence the topology of the recombination reaction.
There is no theoretical size limitation. PCR products between 100 bp and 11 Kb have been readily cloned into a pDONR Gateway vector. Other DNA pieces as large as 150 kb with att sites will successfully recombine with a Gateway-compatible vector. Overnight incubation is recommended for large inserts.
It depends on whether the lambda vector has recombination (att) sites that are compatible with the design of our system. Without att sites, the library would definitely not be Gateway compatible.
Yes, the Gateway LR reaction allows you to transfer a cDNA library made in Gateway entry vectors into Gateway destination vectors with no significant effect on the library's average insert size or insert size range. Thus, the library's complexity is maintained after the LR reaction. The library transfer reaction protocol is found in the CloneMiner II cDNA Library Construction Kit manual.
There is no recommended method that would maintain the complexity of the original library. The best option is to create a new library using the CloneMiner II cDNA Library Construction Kit. This kit will allow you to clone, via a BP reaction, all the generated cDNAs into a Gateway-compatible vector.
It depends upon the library. Only libraries in pCMVSport6 or pCMVSport6.1 have attB sequences.
Standard desalted purity is generally sufficient for creating attB primers. We examined HPLC-purified oligos for Gateway cloning (about 50 bp long) and found only about a 2-fold increase in colony number over standard desalted primers. If too few colonies are obtained, you may try to increase the amount of PCR product used and/or incubate the BP reaction overnight.
Columns are stored at 4 degrees C. Over time the ethanol can evaporate, leaving behind an air bubble. To correct this, users should wash the columns with one volume of dH2O and then use the "thumb trick". Add the dH2O to the column, if it is still flowing slowly, place a gloved thumb over the top of the column, push down a little, and then raise up (you can do this 2-5 times). Similar to a pump, this helps the flow rate and gets rid of the air bubble that was preventing a good flow. This is the procedure that is used at our training center.
Labeling can be carried out in either reaction, but labeling during first-strand synthesis allows users to detect problems in the RNA preparation or in the first strand components. These problems can be solved before going to the time and expense of the second-strand synthesis.
Three kits are available for making cDNA libraries.
(1) CloneMiner cDNA Library Construction Kit for construction of high-quality Gateway cloning-compatible cDNA libraries without the use of restriction enzyme cloning. This system uses highly efficient recombinational cloning, resulting in a higher number of primary clones compared to standard cDNA library construction methods.
(2) SuperScript Plasmid System relies on SuperScript II Reverse Transcriptase (RT) for high-percentage conversion of purified mRNA to first-strand cDNA. The cDNA is directionally inserted into the Gateway cloning-compatible pCMV.SPORT6 vector as Not I-Sal I fragments. The library can be used directly for transient expression in mammalian systems without the need for subcloning. In addition to their utility within the Gateway technology platform, the resulting clones can also be subcloned by traditional restriction enzyme cloning methods.
(3) The SuperScript Choice System offers two priming methods: oligo (dT) or random hexamers and uses SuperScript II RT. This system is for nondirectional cloning using EcoR I adapters.
The most common reason that nonspecific sequences are amplified is that the annealing temperature in your PCR program is much lower than the actual melting temperature of your primers. Recalculate the melting temperature of your primers using the Tm calculator tool (available on the GeneAmp PCR System 9700, 9800, and Veriti Thermal Cycler). Then, in your PCR program --as a starting point--set an annealing temperature that is no more 2 degrees below your calculated Tm of for the primers.
Find additional tips, troubleshooting help, and resources within our PCR and cDNA Synthesis Support Center.
DNA concentration is a critical parameter in PCR amplification. If too much DNA is used, a smear will often result (due to concatamer formation of the target DNA that can occur at higher concentrations). When reamplifying PCR product, a good starting concentration is 10 pg. If the DNA cannot be quantified, it may be necessary to set up reamplification reactions using serial dilutions of the original product to obtain good amplification of a single-sized product.
Find additional tips, troubleshooting help, and resources within our PCR and cDNA Synthesis Support Center.
PCR has been used for random mutagenesis of a specific DNA region. The method for creating these random mutations uses conditions that reduce the fidelity of AmpliTaq DNA Polymerase. Briefly, DNA is amplified in the presence of buffer, manganese, and an unequal molar concentration of dNTPs.
Find additional tips, troubleshooting help, and resources within our PCR and cDNA Synthesis Support Center.