June 7 - June 29

No labwork due to moving of the lab.

June 30 - July 31

General
Electrocompetent E. coli cells were made according to the protocol. Transformation efficiency was very high (could not count the colonies, really).

Moving dCas9 to pET26B
New PCR products were made of pdCas9 and pET26B. I proceeded with purification and digestion as usual, but added a step with alkaline phosphatase (CIP, NEB).

Performed ligation and electroporation of ligation. This time cloning was more successful: some colonies on ligation mixture, no colonies on backbone only control.

Colony PCR revealed that some colonies probably contained the correct construct. This was verified by sequencing.

Collection and construction of pEVOL plasmids
We received the biocontainment strains from Harvard, from which pEVOL-BipA was extracted (Machery-Nagel nucleospin kit).

Construction of pT7-gRNA plasmids The following primers were annealed as inserts:

pBbS5a (RFP) 1766-1785 FWD fwd 5’- TAGGgtggtccgctgccgttcgct-3’

pBbS5a (RFP) 1766-1785 FWD rev 5’- AAACagcgaacggcagcggaccac-3’

pBbS5a (RFP) 1739-1758 REV fwd 5’- TAGGaactttcagtttagcggtct -3’

pBbS5a (RFP) 1739-1758 REV rev 5’- AAACagaccgctaaactgaaagtt -3’

pBbS5a (RFP) 1821-1840 FWD fwd 5’- TAGGcaaagcttacgttaaacacc -3’

pBbS5a (RFP) 1821-1840 FWD rev 5’- AAACggtgtttaacgtaagctttg -3’

pBbS5a (RFP) 1803-1822 REV fwd 5’- TAGGtggaaccgtactggaactgc -3’

pBbS5a (RFP) 1803-1822 REV rev 5’- AAACgcagttccagtacggttcca -3’

We tried at first constructing the pT7-gRNA plasmids using protocol described in Jao et al. (2014), but this gave a lot of false positive colonies (on plates transformed without any insert).
Still, some plasmids were isolated from colonies of plates with insert, and digested with SalI-HF and ScaI-HF. Any positive clones should not be cut by SalI, because this restriction site is only present in the original backbone. Expected bands: 759 bp and 1782 bp. No positive clones were found.

The next strategy was to digest with BsmBI and SalI, isolate the linearized plasmid from gel, and proceed with a href="https://static.igem.org/mediawiki/2016/7/76/T--Wageningen_UR--Ligation.pdf">ligation.

This did give us some positive clones.

Procedure was repeated for gRNA 3 and 4. Results were later confirmed by sequencing (however, it turned out that gRNA 3 was not correct after all. It took another round of picking colonies/digestion/sequencing before we also got that one right).

Mutagenesis of dCas9-pET26B
The Ala10TAG and Ala840TAG mutations were introduced by mutagenesis PCR, using the following primers:

dCas9 Ala10TAG fwd 5'-ggcaaaaatggataagaaatactcaataggcttatagatcggcacaaatagcgtc-3'

dCas9 Ala10TAG rev 5'-gacgctatttgtgccgatctataagcctattgagtatttcttatccatttttgcc-3'

dCas9 Ala840TAG fwd 5'-taatcgtttaagtgattatgatgtcgattagattgttccacaaagtttccttaaagacg-3'

dCas9 Ala840TAG rev 5'-cgtctttaaggaaactttgtggaacaatctaatcgacatcataatcacttaaacgatta-3'

First PCRs revealed that only the Ala840TAG PCR was successful, as was revealed by gel electrophoresis (expected band size for both: 9077 bp).

The Ala10TAG mutation worked after addition of GC enhancer to the PCR mixture.

Mutations were verified after sequencing of isolated plasmids.

Aug 1 - Aug 31

Expression of Cas9-pET26B in C321ΔA
Cas9-pET26B constructs as well as iGEM-Cas9 and the original pdCas9 were transformed in E. coli C321ΔA as described in Lajoie et. al (2013) protocol¹ for electroporation, successfully. Later, also, pEVOL-BipA, pEVOL-pAzF and pEVOL-pBpF were transformed into C321ΔA, both with and without Cas9-pET26B constructs.

A first expression experiment was done with 50 ml overnight cultures of C321ΔA + Cas9 construct, in LB with the appropriate antibiotic.
Cells were spun down, resuspended in 10 ml lysis buffer (50mM Tris-HCL, 250 mM NaCl, 1mM EDTA) and lysed by sonication (4x15 sec, 25Am).
Protein concentrations were measured with a Bradford assay.

20 ug of each extract was loaded on SDS to check for Cas9 expression. The expected weight of Cas9 is 156 kDa, of dCas9-Ala10TAG is 1 kDa (can’t be seen anyways), and of dCas9-Ala840TAG it is 97 kDa. No such bands could be observed (possible also due to a background band of the same size)

because for the original iGEM construct, the band seemed to be a bit more pronounced, I grew new cultures and repeated the experiment. This time, it was really obvious that expression levels were too low.

in vitro transcription of guide RNAs By the time of transcription, guide 3 had not been verified by sequencing yet, so only guide 1, 2 and 4 were transcribed and purified, according to the protocol.

I only have a picture of the gel after cutting the RNA bands, but they were present.

After purification, guide 2 and 4 had decent concentrations of ~350 ng/uL. Guide 1 had only 35 ng/uL.

Cloning of Cas9 variants in expresso vector
After discussion with an employee in the departement who has experience expressing Streptococcus pyogenes Cas9, it was decided that expression from pdCas9 is probably too low to visualize on SDS-PAGE, and perhaps not suitable for further in vitro testing.
So it was decided to clone Cas9 in the Expresso c-rham vector system.

First, Cas9 variants and the Expresso vector were amplified by PCR. The following reactions were performed:

Expresso
fwd: CATCATCACCACCATCACTAATAG
Rev: CATATGTATATCTCCTTCTTATAGTTAAAC
Annealing T: 59ºC, elongation time 2.5 minutes.
Expected band size: 2275 bp


iGEM Cas9
Fwd: gtttaactataagaaggagatatacatatgGATAAGAAATACTCAATAGGCTTAGATATC
Rev: gccgctctattagtgatggtggtgatgatgGTCACCTCCTAGCTGACTCAAATC
Annealing T: 64ºC, elongation time 2.5 minutes.
Expected band size: 4088 bp


dCas9 & Ala840TAG:
Fwd: gtttaactataagaaggagatatacatatgGATAAGAAATACTCAATAGGCTTAGCTATC
Rev: gccgctctattagtgatggtggtgatgatgGTCACCTCCTAGCTGACTCAAATC
Annealing T: 66ºC, elongation time 2.5 minutes.
Expected band size: 4088 bp

Ala10TAG:
Fwd: gtttaactataagaaggagatatacatatgGATAAGAAATACTCAATAGGCTTATAGATC
Rev: gccgctctattagtgatggtggtgatgatgGTCACCTCCTAGCTGACTCAAATC
Annealing T: 64ºC, elongation time 2.5 minutes.
Expected band size: 4088 bp


Positive control: Some ~2000 bp thing from Thomas with iGEM prefix and suffix primers.

Fragments were checked by gel electrophoresis.

PCR products were cleaned with Zymo kit (hyperlink), eluted in water and assembled by Gibson Assembly. A vector : insert ratio of 1 : 2 was used, with 100 ng vector. 1 uL of Gibson mixtures were transformed in 25uL commercial competent cells (NEB) according to the accompanying protocol and plated on LB plates with kanamycin.

Colonies that came up were verified with Colony PCR.
Primers that were used:
Fwd: TTGAAGGGTAGTCCAGAAG
Rev: CATATGTATATCTCCTTCTTATAGTTAAAC
Annealing T: 46ºC, elongation time 3 minutes.
Expected band size: 2647 bp.

PCRs were verified using gel electrophoresis. It seemed that there were a lot of positive colonies.

Correct clones were confirmed by sequencing.

Collection and construction of pEVOL plasmids
pEVOL-Asp was constructed according to the yeast assembly protocol.

pEVOL-pAzF
Fwd: ACTAGTGCATGCTCGAGCAG
Rev: CCTCCTGTTAGCCCAAAAAAACGGGTATG
Annealing T: 68ºC, elongation time 2 minutes.
Expected band size: ~3320 bp

pYES2
Fwd: gagcaggcttttttactagtACTCTTCCTTTTTCAATGGG
Rev: aaagcaaattcgaccctgagctgctcgagcatgcactagtAAATATTTGCTTATACAATCTTCC
Annealing T: 56ºC, elongation time 2 minutes.
Expected band size: 2667 bp

gBlock1
Fwd: gagcaggcttttttactagtACTCTTCCTTTTTCAATGGG
Rev: ACAGGGTATTGCTTACGTACCAACTC
Annealing T: 66ºC, elongation time 2 minutes.
Expected band size: 1203 bp

gBlock2
Fwd: TTGCTCATGAAATTGAGTTGGTACGTAAG
Rev: CCCATTGAAAAAGGAAGAGTACTAG
Annealing T: 64ºC, elongation time 2minutes.
Expected band size: 1230 bp

PCR products were verified using gel electrophoresis.

PCR products were cleaned up using the Zymo kit (hyperlink).

Then, yeast assembly was performed using the protocol, with competent yeast cells received from a supervisor.
From the resulting colonies, 6 were picked for plasmid isolation. Only 3 of them had some plasmid yield, which were checked for correct assembly using OneTaq PCR.

PCR reactions that were performed:

pEVOL fwd and gBlock 1 rev primers, annealing T: 56ºC, elongation 4 minutes. Expected fragment size: 4469 bp.
gBlock 1 fwd and gBlock 2 rev primers, annealing T: 50ºC, elongation 4 minutes. Expected fragment size: 2318 bp.

gel electrophoresis reveiled fragments of the right size for colony 2 and 3.

Eventually, the plasmid from colony 3 was transformed successfully in E. coli, miniprepped and sent for sequencing. The following mutations were present: Tryp156Cys, Gly321Val and Gly525Cys. Because there was no time to check other clones, I continued with this plasmid anyways.

Expression of Cas9-expresso constructs in C321ΔA
Both the acquired Cas9-expresso constructs as well as pEVOL-Asp were transformed into C321ΔA as described in Lajoie et al. (2013)¹.

Sept 1 - Okt 10

Expression of Cas9-expresso constructs in C321ΔA
An expression experiment was performed with 3 ml cultures induced overnight with rhamnose, arabinose and synthetic amino acids when applicable. This yielded no visible Cas9 bands. The same happened when 5 ml cultures where induced for 4 hours. What worked, was the protocol with bigger volumes followed by Ni-NTA purification (the majority of the actual work with the FPLC was performed by a supervisor)

First, samples were purified as described, but with addition of DNAse. This gave good yields, but DNAse remained in the purified fractions as was later found out during in vitro Cas9 assays. However, without DNAse also a good yield was obtained.

No Cas9 biobrick?
When I started making the constructs for the Cas9 kill switch, two approaches were taken: taking the Cas9 that is available in the iGEM registry (BBa_K1218011) and pdCas9 (Addgene plasmid # 46569) as a starting point for making mutations and expressing Cas9. I did not manage to transfer BBa_K1218011 to another backbone. Furthermore, when cultures transformed with BBa_K1218011 were checked for Cas9 expression with SDS-PAGE, no convincing Cas9 band could be observed. Because of time limitations I decided to continue working with the Addgene construct for making the mutations, and chose an established system for protein expression. For that reason I did not submit any Cas9-biobricks. Furthermore, the pEVOL construct containing an aminoacyl-synthetase and a tRNA for introducing BipA in response to the TAG stopcodon were isolated from a strain kindly received from George Church (described in Mandel et al., 2015). The MTA that was signed to receive the strain does not allow for redistribution.

References

1. Lajoie, M. J., Rovner, A. J., Goodman, D. B., Aerni, H. R., Haimovich, A. D., Kuznetsov, G., ... & Rohland, N. (2013). Genomically recoded organisms expand biological functions. Science, 342(6156), 357-360. ↩