Cloning

If not otherwise stated all methods were done according to the protocol of the manufacturer.

Cloning methods

Gibson Assembly

Plasmids, that were judged to be assembled in the best way via Gibson Assembly, were generated using NEBuilder HiFi DNA Assembly Kit.

T4 Ligation

Plasmids, that were judged to be assembled in the best way via Ligation, were generated using Qiagen T4 Ligase.

Digestion for cloning

To extract desired DNA fragments for the cloning process the following protocol has been used (Tab. 1).

Table 1: Components of a restriction digest

If two restriction enzymes were used simultaneously the right conditions were determined by using 'NEB Double Digest Finder' or 'Thermo scientific double digest calculator' online tool.

The reaction was stopped after 1-4 hours by adding 10x Orange G, 6x NEB Purple or 6x Thermo Scientific loading dye to the sample. After this the sample was analyzed by agarose gel electrophoresis.

Gel extraction for cloning

Extraction of amplified DNA fragments or digested fragments from agarose gels was performed using the QIAquick gel extraction kit from Qiagen.

Site directed mutagenesis

To get rid of unwanted restriction sites, because they were forbidden by either the iGEM cloning standard or by our own, a site directed mutagenesis (SDM) was used. Here the exchange of nucleotides is accomplished by performing a PCR with a primer containing the mutated nucleotide. Afterwards, the PCR fragments were assembled via Gibson assembly or T4 ligation.

Compatible end assembly

To clone multiple repetitive DNA fragments in succession plasmids was generated suitable for a compatible end assembly. These plasmids contained from 5’ end to 3’ XbaI restriction site, an enhancer element, a NheI restriction site and a BglII restriction site.

To perform the compatible end assembly two different restriction digests of the same plasmid have to be performed. The first contains XbaI and BglII. The second contains NheI and BglII. After separation and extraction of the desired fragments via agarose gel electrophoresis, a T4 ligation is performed. The resulting cloning scar can no longer be cut by either NheI or XbaI. This process can be repeated as often as desired with the resulting plasmids

PCR methods

PCR

Amplification of DNA fragments was performed by using NEB Q5 High Fidelity or NEB One Taq polymerase.

Extension PCR

To generate the DNA fragments containing overlapping sequences for Gibson assembly an extension PCR was performed using NEB Q5 High Fidelity polymerase.

Preparation and Handling

Culture conditions

Liquid overnight cultures of E. coli strains, regardless of the fact if there were containing plasmids or not, were incubated for 12 – 16 hours in LB medium at 37°C and 200 rpm. The only exception were E. coli strains containing lentiviral transfer plasmids, these were incubated at 30°C to ensure higher plasmid concentrations. Solid cultures were incubated on 1.5 % LB Agar plates at 37°C.

Selection of E. coli was performed by adding the appropriate antibiotic to the LB medium or LB plates. The following antibiotic concentrations were used: ampicillin at a final concentration of 100 µg/mL, chloramphenicol at 25 µg/mL and kanamycin at 50 µg/mL (Davis et al., 2012).

Glycerol stocks

To store bacterial strains 500 µL of liquid overnight culture were mixed with 500 µL of 50 % (v/v) glycerol diluted in ddH₂O. Afterwards the cryotube was inverted 4 to 6 times and placed in a -80°C freezer for longterm storage. For overnight cultures, the stock were scraped at the surface with an pipette tip and medium inocculated with it (Davis et al., 2012).

Preparation of chemically competent E. coli

Competent E. coli were produced using the Zymo Research Mix & Go E. coli Transformation Kit.

Transformation

Chemically competent E. coli strains were transformed by adding 2 – 10 µL of T4 ligation or Gibson assembly reaction mix containing the appropriate plasmids. Afterwards the transformed cells were incubated for 1 hour in 1000 µL LB medium containing no antibiotics, at 37°C and 300 rpm, followed by spreading on a LB agar plate containing the appropriate antibiotic resistance. The spread cells were incubated overnight at 37°C.

Subsequently, 3 - 10 colonies were picked per plate and inoculated in 3 - 5 mL of LB medium again containing the appropriate antibiotic and incubated overnight (Davis et al., 2012).

Plasmid preparation

The preparation of plasmids was performed using kits from Qiagen,Jena Biosience, Promega and Zymo Research, according to their provided protocol.

Agarose gels

Amplified or digested DNA samples were supplemented with the appropriate amount of 10x Orange G, 6x NEB Purple or 6x Thermo Scientific loading dye and loaded on a 1 - 2 % (w/v) agarose TAE gel.

TAE agarose gels were produced by mixing agarose with 1x TAE buffer. Afterwards the mixture was microwaved until the agarose was completely dissolved. Staining of the DNA was performed by the PeqGreen DNA dye at the recommended concentration.

The gel was subjected to electrophoresis at 100 – 130 V for 15 - 30 minutes or until a sufficient separation of the bands was observable. Visualization of the separated DNA fragments in the gel was performed by an ultraviolet light imager. A NEB 2-log DNA ladder or a Thermo Scientific 1kb+ DNA ladder were included as molecular size marker (Davis et al., 2012).