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查看更多产品信息 BLOCK-iT™ Adenoviral RNAi Expression System - FAQs (K494100)
10 个常见问题解答
Yes. The miR miRNA vectors are Gateway cloning compatible, and you could use Gateway cloning to transfer the miR miRNA expression cassette to any of our Gateway-adapted viral expression vectors.
No. The ViraPower system uses adenovirus type 5. Adenoviruses (Adenoviridae) and adeno-associated viruses (Parvoviridae) are completely different. Adeno-associated viruses are often associated with adenovirus infections, hence the name. Since they are thought to be virtually non-pathogenic, they are attractive vectors for gene therapy. The disadvantage is that they can package only about half the foreign DNA that adenoviruses can.
Clone your gene of interest into the pAd/CMV/V5-DEST (or pAd-PL-DEST if you want to use your own promoter). Prior to cloning, if desired, propagate this vector in One Shot ccdB Survival 2 T1R Competent Cells (Cat. No. A10460) as described below. After cloning your gene of interest, propagate in E. coli strain TOP10. pAd/CMV/V5-GW/lacZ is provided as a positive control vector for expression.
Digest recombinant plasmid with Pac I to expose the ITRs (inverted terminal repeats).
Transfect (we recommend Lipofectamine 2000 reagent) E1-containing cells (293A cells) with linear DNA (only 10% of transfected cells will make virus).
Infected cells will ball up, and release virus to surrounding cells, which in turn will be killed and ball up. Look for plaques in the monolayer created by areas cleared by detaching, balled up cells (it takes 8-10 days to see visible plaques from this initial transfection).
Collect a crude viral lysate.
Amplify the adenovirus by infecting 293A producer cells with the crude viral lysate. Harvest virus after 2-3 days when cells ball up. Determine the titer of the adenoviral stock by performing a plaque assay. The virus generated is adenovirus type 5 (subclass C).
Add the viral supernatant to your mammalian cell line of interest to transduce cells.
Assay for recombinant protein of interest.
Once you have your gene of interest in the adenoviral vector, you can simply re-amplify when you need more of the virus. You do not need to repeat cloning steps and transfections each time.
When cloning or propagating DNA with unstable inserts (such as lentiviral DNA containing direct repeats), we recommend using the following modifications to reduce the chance of recombination between direct repeats:
- Select and culture transformants at 25-30 degrees C.
- Do not use "rich" bacterial media as they tend to give rise to a greater number of unwanted recombinants.
-If your plasmid confers chloramphenicol resistance, select and culture transformants using LB medium containing 15-30 µg/mL chloramphenicol in addition to the antibiotic appropriate for selection of your plasmid.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
Ultracentrifugation is the most commonly used approach and is typically very successful (see Burns et al. (1993) Proc Natl Acad Sci USA 90:8033-8037; Reiser (2000) Gene Ther 7:910-913). Others have used PEG precipitation. Some purification methods are covered by patents issued to the University of California and Chiron.
Adenovirus is concentrated using CsCl density gradient centrifugation (there is a reference for this procedure in our adenovirus manual) or commercially available columns.
This depends entirely on the target cell. Adenovirus requires the coxsackie-adenovirus receptor (CAR) and an integrin for efficient transduction. Lentivirus (with VSV-G) binds to a lipid in the plasma membrane (present on all cell types). With two totally different mechanisms of entry into the cell, there will always be differences in transduction efficiencies. However, the efficiency of transduction for both viral systems is easily modulated by the multiplicity of infection (MOI) used.
We use mycoplasma-tested Gibco FBS (Cat. No. 16000-044) without any modifications. We have observed that when 293FT cells are cultured in the presence of this FBS following the instructions in the manual, virus production is better than that obtained with many other serum sources.
We use the following plasticware for 293A and 293FT cells:
T175--Fisher Cat. No. 10-126-13; this is a Falcon flask with 0.2 µm vented plug seal cap.
T75--Fisher Cat. No. 07-200-68; this is a Costar flask with 0.2 µm vented seal cap.
100 mm plate--Fisher Cat. No. 08-772E; this is a Falcon tissue culture-treated polystyrene plate
We get excellent adherence on these plates under routine cell culture/maintenance conditions (expect cell lysis in 293A cells when making adenovirus).
Viral vectors:
Store lentiviral and adenoviral expression vectors (plasmid DNA) at -20 degrees C. Due to their relatively large sizes, we do not recommend storing these vectors at -80 degrees C, as the vector solutions will completely freeze and too many freeze thaws from -80 degrees C will affect the cloning efficiency. At -20 degrees C, the vectors will be stable but will not freeze completely. Glycerol stocks of vectors transformed into bacteria should always be stored at -80 degrees C.
Virus:
Both adenovirus and lentivirus particles should be aliquoted immediately after production and stored at -80 degrees C.
Lentivirus is more sensitive to storage temperature and to freeze/thaw than adenovirus and should be handled with care. Adenovirus can typically be frozen/thawed up to 3 times without loss of titer, while lentivirus can lose up to 5% or more activity with each freeze/thaw. It is recommended to aliquot your virus into small working volumes immediately after production, freeze at -80 degrees C, and then thaw just one aliquot for titering. This way, every time you thaw a new aliquot it should be the same titer as your first tube.
Adenovirus particles can be kept overnight at 4 degrees C if necessary, but it is best to avoid this. Viruses will be most stable at -80 degrees C.
When stored properly, viral stocks should maintain consistent titer and be suitable for use for up to one year. After long-term storage, we recommend re-titering your viral stocks before use.
Both the lentiviral and adenoviral systems should be used following Biosafety Level 2 (BSL-2). We recommend strict adherence to all CDC guidelines for BSL-2 (as well as institutional guidelines). Thermo Fisher Scientific has also engineered specific safety features into the lentiviral system.
Consult the "Biosafety in Microbiological and Biomedical Laboratories" publication (www.cdc.gov, published by the CDC in the USA, describes BSL-2 handling) and the "Laboratory Biosafety Guidelines" publication (www.phac-aspc.gc.ca, published by the Centre for Emergency Preparedness and Response in Canada) for more information on safe handling of various organisms and the physical requirements for facilities that work with them.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
If you're interested in stable integration and selection, choose the lentiviral system. We offer both a Directional TOPO (D-TOPO) and Gateway version of the kit to provide flexibility in the cloning of the gene of interest.
If you're looking for transient gene expression, choose the adenoviral system. We offer the Gateway cloning method for this product. It should be noted, however, that gene expression from both systems is typically detected within 24-48 hours of transduction, so both systems can be used for experiments of a transient nature. The main difference is that lentivirus integrates into the host genome and adenovirus does not. Higher viral titers are achieved with the adenovirus.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
No, neither lentivirus nor adenovirus can take an insert as large as 9 Kb. Lentiviral packaging limits are around 6 kb and adenoviral packaging limits are around 7-7.5 kb. Above that, no virus is made.
For lentivirus, titers will generally decrease as the size of the insert increases. We have effectively packaged inserts of 5.2 kb with good titer (approx. 0.5 x 10^5 cfu/mL). The size of the wild-type HIV-1 genome is approximately 10 kb. Since the size of the elements required for expression from pLenti vectors add up to approximately 4-4.4 kb, the size of your gene of interest should theoretically not exceed 5.6-6 kb for efficient packaging (see below for packaging limits for individual vectors).
pLenti4/V5-DEST vector: 6 kb
pLenti6/V5-DEST vector: 6 kb
pLenti6/V5/D-TOPO vector: 6 kb
pLenti6/UbC/V5-DEST vector: 5.6 kb
For adenovirus, the maximum packagable size is approximately 7-7.5 Kb (see below for packaging limits for individual vectors).
pAd/CMV/V5-DEST vector: 6 kb
pAd/PL-DEST vector: 7.5 kb