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View additional product information for One Shot™ TOP10F' Chemically Competent E. coli - FAQs (C303003, C303006)
12 product FAQs found
TOP10与TOP10F’细胞的区别仅在于后者包含F’游离体因而带有四环素抗性基因,而且能够从带有f1复制起点的载体菌株中分离单链DNA。F’ 游离体同时还带有lacIq抑制子,因此可用IPTG诱导trc、ta、和lac启动子的表达。TOP10F’细胞需要IPTG诱导进行蓝白斑筛选。
如果插入片段对于宿主细胞有潜在毒性,您可以尝试以下建议:
•转化TOP10或DH5α细胞后,在25-30摄氏度而不是在37摄氏度下孵育。这会降低生长速度并能提高克隆具有潜在毒性的插入片段的几率。
•尝试使用TOP10F’细胞进行转化,但是不在培养板中加入IPTG。这些细胞带lacIq阻抑物抑制从lac启动子起始表达,因此能克隆毒性基因。请注意,没有加入IPTG时不能进行蓝白斑筛选。
•尝试使用Stbl2细胞进行转化。
The only difference between TOP10 and TOP10F' cells is that the latter contain the F' episome that carries the tetracycline resistance gene and allows isolation of single-stranded DNA from vectors that have an f1 origin of replication. The F' episome also carries the lacIq repressor for inducible expression from trc, tac, and lac promoters using IPTG. TOP10F' cells require IPTG induction for blue/white screening.
If the insert is potentially toxic to the host cells, here are some suggestions that you can try:
- After transforming TOP10 or DH5? cells, incubate at 25-30°C instead of 37°C. This will slow down the growth and will increase the chances of cloning a potentially toxic insert.
- Try using TOP10F' cells for the transformation, but do not add IPTG to the plates. These cells carry the lacIq repressor that represses expression from the lac promoter and so allows cloning of toxic genes. Keep in mind that in the absence of IPTG, blue-white screening cannot be performed.
- Try using Stbl2 cells for the transformation.
There are other strains available that may function similarly to Stbl2 cells in stabilizing inserts or vectors with repeated DNA sequences. However, one advantage of Stbl2 cells over many similar strains is that they are sensitive to Kanamycin, so you can use Stbl2 to propagate plasmids containing a Kanamycin resistance marker.
For best results, DNA used in electroporation must have a very low ionic strength and a high resistance. A high-salt DNA sample may be purified by either ethanol precipitation or dialysis.
The following suggested protocols are for ligation reactions of 20ul. The volumes may be adjusted to suit the amount being prepared.
Purifying DNA by Precipitation: Add 5 to 10 ug of tRNA to a 20ul ligation reaction. Adjust the solution to 2.5 M in ammonium acetate using a 7.5 M ammonium acetate stock solution. Mix well. Add two volumes of 100 % ethanol. Centrifuge at 12,000 x g for 15 min at 4C. Remove the supernatant with a micropipet. Wash the pellet with 60ul of 70% ethanol. Centrifuge at 12,000 x g for 15 min at room temperature. Remove the supernatant with a micropipet. Air dry the pellet. Resuspend the DNA in 0.5X TE buffer [5 mM Tris-HCl, 0.5 mM EDTA (pH 7.5)] to a concentration of 10 ng/ul of DNA. Use 1 ul per transformation of 20 ul of cell suspension.
Purifying DNA by Microdialysis: Float a Millipore filter, type VS 0.025 um, on a pool of 0.5X TE buffer (or 10% glycerol) in a small plastic container. Place 20ul of the DNA solution as a drop on top of the filter. Incubate at room temperature for several hours. Withdraw the DNA drop from the filter and place it in a polypropylene microcentrifuge tube. Use 1ul of this DNA for each electrotransformation reaction.
The recommended heat shock time does increase slightly with increasing volume of competent cells. For a 50 µl reaction volume, you should heat shock at 42°C for 30 seconds. For 100 µl, 45 seconds is recommended and for 250 µl, 60 seconds. It is important to do a positive control transformation of pUC19 along with transformation of your ligation product to accurately determine your relative efficiency of transformation.
It may be surprising, but in most cases transformation efficiency per µg of DNA will actually decrease when higher amounts of plasmid are transformed in one reaction. While you may see more colonies on your plates, much of the extra plasmid DNA you added will actually be wasted. Competent cells eventually become oversaturated with DNA, and adding more plasmid beyond that level will not result in any additional colonies. For example, when transforming 10 pg plasmid DNA, the efficiency of TOP10 cells is 1.0x10E9 colonies per µg of DNA that you added. If you transform 1 ng all at once, the overall efficiency is likely to decrease to ~1.0x 10E8 colonies per µg, and transforming 1 µg in a single reaction will likely result in efficiency less than 1.0 x 10E6 colonies per µg.
To maximize colony yield, it is better to transform smaller amounts of DNA in multiple reactions rather than adding all of the DNA to one reaction. This is most important when transforming a library, where you ideally want each plasmid to be represented by a colony after transformation.
While the F' plasmid does contain the ccdA gene that can inhibit or reduce the toxicity of the ccdB gene product, the ccdA expression level is likely to be too low, or inhibition may not be complete, and the bacteria would still be exposed to the ccdB gene product and thus not grow. Therefore, bacterial strains containing the F' plasmid are not recommended as hosts for propagation of ccdB containing vectors.
For propagation of Gateway vectors containing ccdB, we recommend the One Shot ccdB Survival 2 T1R Competent Cells (A10460), which were specifically designed for that purpose. However, please note that these cells are not validated for propagation of other ccdB-containing vectors like the older pZErO plasmids, and in most cases they are not expected to work due to very high levels of ccdB protein expressed in those vectors.
nupG is a mutation for the transport of nucleosides. The nupG site is next to endA on the chromosome, and when endA was mutated by transposon insertion, the nupG site was unintentionally mutated as well. There are no apparent effects of this mutation on cell function or growth.
References: 1) Nghiem, Y. et al. PNAS 85: 2709-2713. 2) Westh Hansen, S.V. et al. Eur. J. Biochem. 168: 385-391.
Single-stranded DNA viral particles like M13 require the presence of an F pilus in order to infect E. coli. This criterion is met by TOP10F', DH5? F'IQ, INV?F', Stbl4, OmniMAX2-T1 and DH12S cells. These cells are not traD mutants, which effectively allows the cells to retain the F' episome. Transforming single-stranded DNA can cause a 100- to 1,000-fold reduction in efficiency compared to viral particles.
Cosolvents may be used when there is a failure of amplification, either because the template contains stable hairpin-loops or the region of amplification is GC-rich. Keep in mind that all of these cosolvents have the effect of lowering enzyme activity, which will decrease amplification yield. For more information see P Landre et al (1995). The use of co-solvents to enhance amplification by the polymerase chain reaction. In: PCR Strategies, edited by MA Innis, DH Gelfand, JJ Sninsky. Academic Press, San Diego, CA, pp. 3-16.
Additionally, when amplifying very long PCR fragments (greater than 5 kb) the use of cosolvents is often recommended to help compensate for the increased melting temperature of these fragments.
Find additional tips, troubleshooting help, and resources within our PCR and cDNA Synthesis Support Center.