Difference between revisions of "Team:SKLMT-China/Notebook Protocol"

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                            Standard Protocol for Making Cells Electrocompetent
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                             Standard Protocol for digestion of the plasmid DNA
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                        Standard protocol for degestion a plasmid
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Revision as of 02:17, 14 October 2018

• use your fresh E.coli culture

• Put the cells on ice (and keep them on ice whenever possible).

• Spin the cells down at 9,000 rpm for 30 sec in the cooling centrifuge at 2°C.

• Discard the supernatant by decanting. Discard as much supernatant as possible.

• Resuspend the pellet in 1 ml of ice cold water by pipetting.

• Spin the cells at 10,000 rpm for 30 sec in the cooling centrifuge at 2°C.

• Discard the supernatant by decanting. Discard as much supernatant as possible.

• Resuspend the pellet in 1 ml of ice cold water by pipetting.

• Spin the cells down at 11,000 rpm for 30 sec in the cooling centrifuge at 2°C.

• Discard the supernatant by decanting and leave about 30 µl.

• Use the cells immediately.

• Add DNA to the cells and pipette the mixture into the chilled 1 mm electroporation cuvette.

• Set the electroporator to 1350 V, 10 µF, 600 Ohms. (This setting belongs to an Eppendorf® Electroporator 2510 using an electroporation cuvette with a gap of 1 mm. Other devices can be used, but the voltage has to be fixed at 1350V and the length of the pulse should be 5 ms.)

• Carefully knock the cuvette on the table to remove air bubbles and dry the metallic sides of the cuvette with a tissue. Do not touch the metallic sides with your hands.

• Place the cuvette into the holder of the electroporator, insert, and push the “pulse” button twice.

• Add 1 ml LB medium without antibiotics to the cuvette. Resuspend the cells carefully by pipetting up and down and pipette back into the reaction tube (avoid air bubbles in the suspension).

• Recover the cultures on an shaking incubator.

• (For future experiments in your lab, prepare a backup plate or backup tubes before starting, buffers are from Qiagen)

• Spin down the cells at 13,200 rpm for 1 minute.

• Discard the supernatant (remove as much as possible).

• Add 200 µl of P1 buffer (keep P1 at 4°C because of the RNaseA in the buffer).

• Resuspend the pellet by vortexing or use a pipette.

• Add 200 µl of P2 buffer (do not place P2 on ice, doing so will cause precipitation).

• Mix the tubes by inversion 5 times.

• Do not allow the lysis to proceed for more than 5 minutes.

• Add 200 µl of P3 buffer (keep P3 at 4°C).

• Mix by inversion 5 times.

• Spin the tubes at 13,200 rpm for 20 min.

• Prepare a fresh labeled 1.4 ml tube for each sample and add 500 µl of isopropanol .

• After centrifugation take out the supernatant with a pipette- avoiding white precipitate- and put it into the tube containing isopropanol.

• Mix by shaking the tubes vigorously.

• Spin the tubes at 13,200 rpm for 20 min.

• Discard the supernatant, invert the tube on a tissue.

• Carefully add 500 µl of 70% ethanol (centrifuge again for 5 min if pellet is only loosely attached to the wall of the tube).

• Discard the ethanol, invert the tube on a tissue.

• You may spin the tube again and remove remaining ethanol with a pipette.

• Dry the pellet for 10-15 min on a heating block (42C), do not overdry it (it is hard to dissolve then).

• For Plasmids: Dissolve the pellet in water (10-40 µl). For BACs: Dissolve the pellet in the digestion mix or dissolve in 8 µl water to send for sequencing.

• Transform the expression plasmid pSC101-BAD-gbaA-tet into the E.coli strain, in which you want to perform recombineering.

• To prepare DNA of the expression plasmid, using any commercial plasmid preparation kit will result in very low yield due to the low copy number of the pSC101 plasmid. Please use our plasmid preparation protocol. To check your prepared expression plasmid rather perform a function test than a digestion analysis.

• To start overnight cultures, pick colonies from the respective plate.

• Inoculate 1.5 ml reaction tubes containing 1.0 ml LB medium plus the appropriate antibiotics (select for BAC or plasmid and for expression plasmid)

• Puncture the cap for aeration.

• Incubate the cultures with shaking at 30°C and 950 rpm o/n.

• Set up punctured reaction tubes containing 1.4 ml fresh LB medium supplemented with the same antibiotics as in the ON culture.

• Inoculate each with 40µl fresh overnight culture.

• Incubate the tubes at 30°C, 950 rpm for 2 hours.

• Add 20 µl 10% L-Arabinose to a final concentration of 0.1%-0.2%. This will induce the expression of the proteins necessary for recombineering.

• Leave some tubes without induction as negative controls

• Incubate at 37°C, 950 rpm for 40 min.

• Use 10% L-arabinose in dH2O, fresh or frozen in small aliquots at -20C

• Use 20 l stock solution per 1.4 ml LB for induction of recombination protein expression from pSC101-BAD-A-tet.

To target your BAC/genome/plasmid at the site(s) you choose, the homologous region must be included in the two oligonucleotides for amplification of a drug selectable cassette. Therefore each oligonucleotide consists of two (or, if desired, three) parts:

• Required Part A (A´ for the other oligonucleotide) is the homology region shared by the target molecule and the linear molecule. Choose the way that you want to engineer your target. Often, you want to delete a section of your target. This is accomplished by replacing this section with the selectable marker. The homology regions are the about 50 bp immediately either side of the deleted section. You can delete from 0bp (i.e. make an insertion) to > 100kb. The exact sequence of the homology regions can be chosen freely, according to which position on the target molecule will be modified.

• Optional Part B (B´ for the downstream oligonucleotide): This part of the oligonucleotide allows useful sequences, such as HA-tags, Myc-tags, His-tags, or restriction sites, multiple cloning sites, site-specific recombination target sites, etc., to be incorporated into the recombinant product B and/or B´. By design, these will be incorporated into the recombinant product exactly where desired. If the introduction of such operational sequences is not needed, this piece can simply be omitted from the oligonucleotide design.

• Required Part C (C´ for the downstream oligonucleotide): This piece, usually 20 to 24 nucleotides long, primes the PCR amplification of the linear molecule from the provided template.

The most efficient way to design primers for modifying BACs or chromosomes using the Red/ET system is to make the electronic map of the final construct by pasting in the desired sequence into the gene to be modified. Any program like Gene Construction Kit, DNA Strider, Gene Inspector etc. will do. Based on the final construct, copying and pasting the inserted sequence plus 50 bp immediately either side of the insertion in a new file gives the electronic map of the PCR product for recombineering. Copy the upstream primer and send the sequence to synthesizer. Copy the downstream primer and make the reverse complement.

We have no data to tell the relationship of the nucleotide context of the homologous to the recombineering efficiency. With primer design there is sometimes no choice of homology region, if for example you need to change one base pair of a particular gene. But many times you want to knock out a gene and there are no strict rules about where you must do it. Or sometimes you just want to have a marker in a particular region of a chromosome and don’t care precisely where it is. In these cases a 50 bp region that is roughly 50% GC in content is preferred. A long stretch of a single nucleotide should better be avoided.

It is a good idea to take the non-template directed extra A, that Taq polymerase puts on to the end of PCR products, into consideration. It is best to design the oligos in a way that recombination works with both the precise PCR product and the template extended-A products.

Recombineering is often utilizes cassettes with selectable markers. Unwanted background selection is usually caused by residual intact plasmid that was used as PCR template. To reduce or eliminate recombineering background from the PCR template, you can use one of the following 5 methods or combine two of them if necessary.

Template digestion

Perform template plasmid digestion with one or more restriction enzymes with recognition sites, that are present in the plasmid backbone but absent in the drug selectable cassette to be amplified. The digested plasmid DNA needs to be checked by electrophoresis to verify efficient digestion. Furthermore, the digested DNA should be diluted to very low concentration to further reduce the background, since practically 100% digestion is always hard to achieve, especially when an inefficient restriction enzyme has to be used.

Template fragment isolation

Perform template plasmid digestion with one or more restriction enzymes with recognition sites, that are present in the plasmid backbone but absent in the drug selectable cassette to be amplified. Run the digested plasmid DNA on an agarose gel and isolate the fragment needed as template for PCR according to standard protocols.

Fragment isolation

After PCR amplification, separate the PCR-amplified targeting molecule from the template DNA by agarose gel electrophoresis. Isolate the PCR-amplicon using standard procedures. Commercially available fragment-isolation kits can be used according to manufacturer’s instructions.

DpnI digestion

The restriction enzyme DpnI has a 4-basepair recognition site (GATC), and only digests methylated DNA. Since a PCR product (i.e. linear targeting DNA) is not methylated, and template DNA usually is (upon growth in most commonly used bacterial cloning strains [dam+ strain]), DpnI only digests the template DNA and not the linear targeting molecule.

Non-replicable PCR template

Alternatively, suicide plasmids can be used as PCR template. As an example we use plasmids containing the R6K origin of replication. The pir gene encoded protein is essential to initiate the replication of the R6K plasmid. The R6K plasmid without pir gene can only replicate in a pir+-strains such as BW116, EPI100D-pir or EPI100D-pir116 cells, where the pir or the pir116 gene are present on the chromosome. Using R6K plasmids as the PCR template, consequently a pir--strain should be used for recombineering. Because the R6K plasmids cannot replicate in the recombineering strain (pir-), zero background selection is achieved without any effort of removal of the PCR template.

MasterMix
Cut Smart buffer (n + 1) x 0.2 µl
PvuII-HF (n + 1) x 0.2 µl
dH2O (n + 1) x 4.8
Total volume (n + 1) x 6.0 µl

• Add 6.0 µl of the Mastermix to 4.0 µl of the dissolved plasmid DNA

• Incubate for at least 1.5 h at 37°C.

• Load the whole mixture with loading buffer on a 0.7% agarose gel (containing EtBr) and perform electrophoresis. Take a picture.