Team:Cambridge/Experiments/Synthetic Reflectin PCR and Construction of GA1 to 6

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Synthetic Gene Amplification & Plasmid Construction

Synopsis

The synthetic genes were extracted from the filter paper on which they were sent, and amplified by PCR.

Eight plasmids were then constructed, named GA1-6, GA13 and GA14 as shown below. Each puts reflectin expression under the control of pBAD promoter, an arabinose inducible promoter. HIS tags were included on some of the constructs in order to purify the protein for the in vitro work. We also put both reflectin A2 and 1B in a low expression plasmid. In addition, we created Reflectin A1 translational fusions with GFP at the C-terminus, which allowed for tracing the localization of reflectin in a bacterial cell at high and low level of expression.

Name Description
Gene Plasmid Promoter
GA1 Reflectin A1 on PSB1A2 (high copy) pBAD promoter
GA2 Reflectin A1 on PSB3K3 (low copy) pBAD promoter
GA3 Reflectin A1 + HIS tag on PSB1A2 (high copy) pBAD promoter
GA4 Reflectin A1 + HIS tag on PSB3K3 (low copy) pBAD promoter
GA5 Reflectin A2 on PSB3K3 (low copy) pBAD promoter
GA6 Reflectin 1B on PSB3K3 (low copy) pBAD promoter
GA13 Reflectin A1 : GFP on PSB3K3 (low copy) pBAD promoter
GA14 Reflectin A1 : GFP on PSB3K3 (low copy) pBAD promoter

These constructs were grown up in E.coli and verified by colony PCR. The plasmids were then miniprepped and stored at -20°C.

Extraction & Amplification

Wendy Crookes-Goodson kindly supported us with three pUC57 plasmids containg reflectin genes: Euprymna scolopes Reflectin 1B, and Loligo pealei Reflectin A1 and Reflectin A2. These are synthetic genes, codon optimized for expression in E.coli, and with all restriction sites removed from the coding region.

The plasmids with the reflectin gene were first extracted from filter paper, and then used to transform competent E. coli cells. A standard miniprep was used to recover the plasmid DNA from the overnight culture of the transformed bacteria in LB. The purpose of this procedure was to amplify and store the plasmid DNA.

Construct Design

For the assembly of the required plasmids, we amplified desired components by PCR and then joined them using Gibson Assembly procedure.

We used three different DNA templates:

  • I13520:pSB1A3, which contains mRFP gene under the control of pBAD promoter. It provided high copy number plasmid backbone and elements required for the expression of the gene of interest, such as pBAD/araC promoter I0500, ribosome binding site B0034 and terminator B0015.
  • J69511:pSB3K3, which contains GFP under the control of R0011 promoter that allows for strong constitutive expression unless it is repressed by LacI. It provided low copy number plasmid backbone and terminator B0015.
  • pUC57 plasmid with reflectin A1/A2/1B coding regions.

The his tag present in GA3 and GA4 constructs was included in primers.

We created high copy number plasmids GA1 and GA3 by replacing mRFP coding region of pSB1A2:I13520 with reflectin A1 coding region.

In the case of low copy number plasmids, GA2 and GA4-6, the respective reflectin coding region was joined to a part of pSB1A2 upstream (carrying pBAD/araC and RBS) and was attached to a part of the pSB3K3 downstream (contributing a terminator and a backbone). We managed to join pBAD/araC promoter and B0015 ribosome binding site with the low copy number plasmid backbone using a pair of primers complementary to the region around the standard annealing site, included in every standard biobrick backbone.

For GA13 and GA14 constructs, the template DNA we used were GA1 and GA2 plasmids, respectively. We inserted GFP gene E0040, contributed by J69511:pSB3K3 plasmid, between the reflectin coding region and the B0015 terminator.

Sequences of the primers used in the experiment and their predicted melting temperatures are the following:

Name Sequence Tm
1-a1 AGAAAGAGGAGAAATACTAGATGGGATCCATGAACCGTTACC 67.9°C
1-his ATACTAGATGCATCATCACCATCACCACATGGGATCCATGAACCGTTAC 64.9°C
1-a2 GAAAGAGGAGAAATACTAGATGAATCGTTATATGATGCGC 61.7°C
1-1b AGAAAGAGGAGAAATACTAGATGGGATCCATGAATCGC 63.9°C
2-a1 CTGGCTCTAGTATTAGTACATGTGGTAATCGTAATAATTAC 59.9°C
2-a2 CTGGCTCTAGTATTAATACCAACTATTATAGTTATCATACATATTTG 59.7°C
2-1b ATGCCTGGCTCTAGTATTAATAACAATAATCGTTCATGCC 60.9°C
3-a1 ATTACGATTACCACATGTACTAATACTAGAGCCAGGCATCAAATAAAAC 64.4°C
3-a2 ATAACTATAATAGTTGGTATTAATACTAGAGCCAGGCATCAAATAAAAC 64.4°C
3-1b GCATGAACGATTATTGTTATTAATACTAGAGCCAGGCATCAAATAAAAC 64.4°C
4-a1 GGTAACGGTTCATGGATCCCATCTAGTATTTCTCCTCTTTCTCTAGTAGCTAG 65.0°C
4-his CATGGATCCCATGTGGTGATGGTGATGATGCATCTAGTATTTCTCCTCTTTCTCTAGTAG 60.0°C
4-a2 GCGCATCATATAACGATTCATCTAGTATTTCTCCTCTTTCTCTAGTAGCTAG 60.5°C
4-1b GCATGAACGATTATTGTTATTAATACTAGAGCCAGGCATCAAATAAAAC 64.4°C
5 VF2 55°C
6 primer donated by our supervisor James
7 TATTACGATTACCACATGTACATGCGTAAAGGCGAAGAGC 64.66°
8 GTTTTATTTGATGCCTGGCTCTAGTATCATTTGTACAGTTCATCCATACC 61.84°
9 GGTATGGATGAACTGTACAAATGATACTAGAGCCAGGCATCAAATAAAAC 64.41°
10 AGCTCTTCGCCTTTACGCATGTACATGTGGTAATCGTAATAATTACG 60.62°

The pictures below give an overview of the assembly of the plasmids:

GA1 construct
GA2 construct
GA3 construct
GA4 construct
GA5 construct
GA6 construct
GA13 construct
GA14 construct

Assembly of GA1, GA2, GA3 and GA4 - First Attempt

PCR

In the first round of PCR, we amplified fragments required for the assembly of GA1, GA2, GA3 and GA4 constructs.

Hold 95°C 2 min
Cycling ×30 Denaturing 95°C 10 s
Annealing 55°C 20 s
Elongation 72°C 150 s

We decided to use the 55°C annealing temperature, although the predicted temperature for most primers is 5-10°C higher, because of a low annealing temperature of the VF2 primer.

  • Primers and template DNA provided by our supervisor Paul served as a positive control, but eventually we did not detect any products on the gels.


The pictures below present results of the gel electrophoresis of PCR products.

The order of samples: HyperLadder I, GA1-1, GA1-2, positive control, HyperLadder I, GA2-1, GA2-2 and GA2-3.
The order of samples: HyperLadder I, GA3-1 and GA3-2.
The order of samples: HyperLadder I, GA4-1, GA4-2 and GA4-3.
  • In most cases position of a band matches the expected length of DNA fragment. The only exception are GA1-2 and GA3-2 products. According to the position on the gel the length of these DNA fragments is 4-5kb, whereas the predicted length is 3.5kb. Our hypothesis is that we were provided pSB1AK3 backbone instead of pSB1A3 backbone.
  • For GA1-1, GA2-1, GA3-1 and GA4-1 we obtained two bands: 1000bp and 400bp, with the latter resulting from non-specific priming most probably. We extracted the two bands for GA1-1, GA2-1 and GA4-1 products, labelling the 1000kb and 400bp fragments GAX-1a and GAX1-b respectively.
  • The molecular weight marker that we used in all gels is HyperLadder I, which produces regularly spaced bands ranging from 200 to 10,000bp.

For the gel extraction of DNA we followed the protocol, assuming that one slice of gel is 100μl.


Gibson Assembly

We conducted Gibson Assembly of GA1, GA2, GA3 and GA4 constructs according to the protocol. The volumes of Master Mix and solutions of amplified DNA were the following:

GA1 GA2 GA3 GA4
15µl Master Mix 15µl Master Mix 15µl Master Mix 15µl Master Mix
2.5µl GA1-1a 1.67µl GA2-1a 2.5µl GA3-1 1.67µl GA4-1a
2.5µl GA1-2 1.67µl GA2-2 2.5µl GA3-2 1.67µl GA4-2
1.67µl GA2-3 1.67µl GA4-3


Transformation

We transformed competent E.coli cells according to the following protocol. We cultured each class of transformants on four different plates.

GA1 and GA3 GA2 and GA4
Plate 1 non-induced (10μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 2 non-induced (100μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 3 induced (10μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose
Plate 4 induced (100μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose

After overnight incubation at 37°C of transformed E.coli cells, we could see colonies on only some of our plates. We examined successful plates under a fluorescence microscope to check if the cells had been transformed with a carry-through of the template DNA used in the initial PCR reactions. The risk of contaminating Gibson Assembly reactions with template DNA was fairly high because circular DNA of around 4kb was likely to co-localize with the linear PCR products.

Type of plasmid Expected phenotype of transformed colonies
LB + Antibiotic LB + Antibiotic + Arabinose
Reflectin A1 expression plasmid
desired product
No fluorescence No fluorescence
I13520:pSB1A3 plasmid
template DNA
No fluorescence RFP red fluorescence
J69511:pSB3K3 plasmid
template DNA
GFP green fluorescence GFP green fluorescence


These are the results of the examination of transformants:

GA1 one culture on LB + ampicillin 10μl plate no fluorescence detected
GA2 no colonies observable -
GA3 colonies on all plates no fluorescence detected
GA4 colonies on all plates green fluorescence on induced and non-induced plates


Colony PCR

We decided to conduct colony PCR of E.coli transformed with GA1 and GA3 constructs in order to confirm successful assembly of the plasmids.

  • We prepared overnight liquid cultures of GA3 and GA1 transformants, both in LB + amplicillin and LB + amplicillin + arabinose medium. We picked 6 colonies, labelled a-f, from GA3 LB + ampicillin 100μl plate, and one colony, labelled x, from GA1 LB + ampicillin 10μl plate.
  • We performed colony PCR using Taq polymerase according to the following protocol, using I13520:pSB1A3 plasmid as a positive control. We used standard VR and VF2 primers, as indicated on the diagrams below:
Cam igem-GA1-diagnostic.jpg
Cam igem-positivecontrol-diagnostic.jpg
Expected lengths of products:
Positive control ~2400 bp
GA1 insert ~2800 bp
GA3 insert ~2800 bp
  • Time profile used in the PCR machine:
Hold 1 95°C 6 min
Cycling ×30 Denaturing 98°C 10 s
Annealing 55°C 30 s
Elongation 72°C 180 s
Hold 2 72°C 5 min
  • As we can see from the picture of the agarose gel, c-f and x colonies carried correctly assembled plasmids. We decided to extract plasmids from and prepare glycerol stocks of these successful transformants.
The order of samples: HyperLadder I, GA3a, GA3b, GA3c, GA3d, HyperLadder I, GA3e, GA3f, positive control, GA1x.
  • We also ran a gel with products of MiniPrep procedure to measure its effectiveness and also check if there were any differences in yield between induced and non-induced liquid cultures.
    The order of samples is the following and we can clearly see that induced cultures gave smaller yield than those non-induced. This proves that replication of multi-copy plasmids acts as a burden for proliferating cells, giving lower densities of liquid cultures.
Cam gel miniprep GA1 GA3.jpg
Well 1 2 3 4 5 6 7
Sample Hyperladder I GA3-c GA3-d GA3-e GA3-f GA1-x Hyperladder I
Culture of origin induced induced mixed with non-induced induced induced non-induced


pSB1AK3 or pSB1A3 backbone?

As a side experiment, we decided to determine whether constructs with pSB1A3 backbone also carry a gene for kanamycin resistance. When preparing glycerol stocks of successful transformants, we cultured GA1x and GA3c bacteria in LB + kanamycin liquid medium in addition to LB + ampicillin medium. After 4 hour incubation at 37° the turbidity of both cultures was the same.
This suggests that GA1 and GA3 contructs carry genes for both ampicillin and kanamycin resistance, which means that we were working with pSB1AK3 instead of pSB1A3 backbone.


Diagnostics

In addition, we performed a series of tests to identify the cause of the low efficiency of transformation. The proposed sources of error included:

  • Low efficiency of DNA gel extraction
  • Unsuccessful Gibson Assembly
  • Low viability of competent E.coli cells

In order to check if gel extraction of DNA was successful, we ran a 1% agarose gel with samples of purified products of the initial PCR reactions. Although we could see distinct, fairly thick bands on the first gels, from which PCR products were purified, bands on the diagnostic gel were very faint, even missing in some lanes.

The order of samples: HyperLadder I, GA1-1a, GA1-2, GA2-1a, GA2-2, GA2-3, HyperLadder I, GA3-1, GA3-2, GA4-1a, GA4-2 and GA4-3.

This indicates that the yield of our extraction procedure was very low and probably this was the main reason why the performed transformation was fairly unsuccessful. Therefore, we decided to repeat PCR reactions, this time at higher 50μl volume, and try different conditions of the gel extraction procedure.


Assembly of GA1, GA2, GA3, GA4, GA5 and GA6 - Second Attempt

PCR

In the second round of PCR, we amplified fragments required for the assembly of GA1, GA2, GA3, GA4, as well as GA5 and GA6 constructs.

  • We performed PCR using Phusion Hot Start DNA Polymerase in 50 μl reaction volume.
  • The time profile used in the PCR machine was the following, the same as the one used before:
Hold 95°C 2 min
Cycling ×30 Denaturing 95°C 10 s
Annealing 55°C 20 s
Elongation 72°C 150 s


We ran PCR products on a 1% agarose gel to separate amplified products from template DNA and primers, as well as to check how efficient and specific the amplification process was.

The order of samples: HyperLadder I, GA1-1, GA1-2, HyperLadder I, GA2-1, GA2-2, GA2-3 and GA2-2.
The order of samples: HyperLadder I, GA3-1, GA3-2, HyperLadder I, GA4-1, GA4-2, GA4-3 and GA4-3.
The order of samples: HyperLadder I, GA5-1, GA5-2, GA5-3, HyperLadder I, GA6-1, GA6-2 and GA6-3.
  • In most cases position of a band matches the expected length of DNA fragment. The only exception are again 4-5kb GA1-2 and GA3-2 products, although the predicted length is 3.5kb.
  • This time we obtained single bands on lanes with amplified reflectin, whereas we observed some additional bands on almost all lanes with amplified backbones of plasmids to be constructed. Most probably these were products of non-specific annealing, which we did not detect on the first gel due to low concentration of these additional products in 25μl reaction. Moreover, these differences emphasize the fact that the amount of non-specific products of DNA amplification can vary greatly between reactions depending on the timing of random mis-annealing events.
  • All components of GA5 and GA6 constructs produced clear fairly thick bands with positions matching expected lengths. No non-specific bands on GA5-1 (Reflectin A2) and GA6-1 (Reflectin 1B) lanes were observed.
  • The molecular weight marker that we used in all gels is HyperLadder I, which produces regularly spaced bands ranging from 200 to 10,000bp.

We also ran a gel with products of extraction to check how efficient the procedure was.

The order of samples: HyperLadder I, GA5-1, GA5-2, GA5-3, HyperLadder I, GA6-1, GA6-2 and GA6-3.
  • We obtained clear distinct bands on each lane loaded with components of GA5 and GA6 Gibson Assembly constructs.


Gibson Assembly

We conducted Gibson Assembly of GA1, GA2, GA3, GA4, GA5 and GA6 constructs according to the protocol. The total reaction volume was 20μl.


Transformation

We transformed competent E.coli cells according to the following protocol. We cultured each class of transformants on four different plates.

GA1, GA3 and positive control GA2, GA4, GA5 and GA6
Plate 1 non-induced (10μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 2 non-induced (100μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 3 induced (10μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose
Plate 4 induced (100μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose

As a positive control, we transformed cells with I13520:pSB1A3 plasmid, expecting to detect RFP fluorescence on induced plates. As a negative control, we plated non-transformed heat-shocked competent cells on LB + kanamycin and LB + ampicillin plates.

After overnight incubation at 37°C we examined plates under a fluorescence microscope to check if the cells had been also transformed with the template DNA used in the initial PCR reactions. The table presents expected phenotype of cells transformed with the correct Gibson Assembly construct or two DNA templates.

Type of plasmid Expected phenotype of transformed colonies
LB + Antibiotic LB + Antibiotic + Arabinose
Reflectin A1 expression plasmid
desired product
No fluorescence No fluorescence
I13520:pSB1A3 plasmid
template DNA
No fluorescence RFP red fluorescence
J69511:pSB3K3 plasmid
template DNA
GFP green fluorescence GFP green fluorescence


We observed colonies on all plates except for the negative control:

GA1 no fluorescence detected
GA2 green fluorescence of some colonies on LB + kanamycin + arabinose plates (both 100μl and 10μl)
GA3 no fluorescence detected
GA4 green fluorescence of some colonies on both induced and non-induced plates
GA5 green fluorescence of some colonies on both induced and non-induced plates
GA6 green fluorescence of some colonies on both induced and non-induced plates
+ve control red fluorescence on LB + ampicillin + arabinose plate (as expected)


Colony PCR

We conducted colony PCR of E.coli transformed with GA1 - GA6 constructs in order to confirm successful assembly of these plasmids.

  • We prepared overnight liquid cultures of transformants - GA1 and GA3 in LB + ampicillin medium, and GA2, GA4, GA5 and GA6 in LB + kanamycin medium. For each class of E.coli we picked four colonies that did not show fluorescence on induced LB + antibiotic + arabinose plates.
  • We performed colony PCR using Taq polymerase according to the following protocol, but we did not include any positive control. We used standard VR and VF2 primers, as indicated on the diagrams below:
Cam igem-GA1-diagnostic.jpg
Cam igem-GA2-diagnostic.jpg
Cam igem-GA5-diagnostic.jpg
Cam igem-GA6-diagnostic.jpg
Expected lengths of products:
GA1 insert ~2800 bp
GA2 insert ~2800 bp
GA3 insert ~2800 bp
GA4 insert ~2800 bp
GA5 insert ~2450 bp
GA6 insert ~2600 bp
  • Time profile used in the PCR machine was the following:
Hold 1 95°C 6 min
Cycling ×30 Denaturing 98°C 10 s
Annealing 55°C 30 s
Elongation 72°C 180 s
Hold 2 72°C 5 min


The order of samples: HyperLadder I, GA1-A1, GA1-A2, GA1-A3, GA1-A4, GA2-K1, GA2-K2, GA2-K3 GA2-K4, GA3-A1, GA3-A2, GA3-A3 and GA3-A4, and HyperLadder I.
The order of samples: HyperLadder I, GA4-K1, GA4-K2, GA4-K3, GA4-K4, GA5-K1, GA5-K2, GA5-K3, GA5-K4, GA6-K1, GA6-K2, GA6-K3 and GA6-K4.
  • We obtained distinct bright bands on a majority of lanes loaded with products of colony PCR, and their position on the gel corresponds to the predicted sizes of these DNA fragments. This suggests that most colonies, except for GA3-A3, GA4-K3, GA6-K1 and GA6-K4 carried correctly assembled plasmids. Therefore, we decided to extract plasmids from and prepare glycerol stocks of successful transformants.


Assembly of GA13 and GA14

PCR

In the third round of PCR, we amplified fragments required for the assembly of GA13 and GA14 constructs.

Hold 95°C 2 min
Cycling ×30 Denaturing 95°C 10 s
Annealing 55°C 20 s
Elongation 72°C 190 s
  • As we can see from photographs of agarose gels, we obtained bands of expected lengths on each lane. However, we also observed a second, about 1000bp, band on lanes with amplified DNA coding for sfGFP. Probably, this was an effect of non-specific priming at 55° which is a fairly low annealing temperature. We extracted DNA from two bands, but DNA from the lower band (GA13/14-1b) was used in the Gibson Assembly reactions.
The order of samples: HyperLadder I, GA13-1, GA13-2, GA14-1 and GA14-2.


Gibson Assembly

We performed Gibson Assembly of GA13 and GA14 construct in 20μ reactions.


Transformation

We transformed competent E.coli cells according to the following protocol. We cultured each class of transformants on four different plates, and we transformed cells with I13520:pSB1A3 as a positive control. Non-transformed heat-shocked competent E.coli cells plated on LB + ampicillin and LB + kanamycin served as a negative control.

GA13 and positive control GA14
Plate 1 non-induced (10μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 2 non-induced (100μl of cell suspension) LB + ampicillin LB + kanamycin
Plate 3 induced (10μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose
Plate 4 induced (100μl of cell suspension) LB + ampicillin + arabinose LB + kanamycin + arabinose

After overnight incubation at 37° we screened colonies under a fluorescence microscope in order to check if they had been transformed with template DNA.

Type of plasmid Expected phenotype of transformed colonies
LB + Antibiotic LB + Antibiotic + Arabinose
Reflectin A1:sfGFP expression plasmid
desired product
No fluorescence Green fluorescence
Reflectin expression plasmid GA1/GA2
template DNA
No fluorescence No fluorescence
J69511:pSB3K3 plasmid
template DNA
GFP green fluorescence GFP green fluorescence

For both classes of transformants, colonies on non-induced plates showed no fluorescence, whereas they showed green fluorescence on induced plates, which served as a confirmation of correct expression of reflectin:GFP fusion.

In order to prepare liquid cultures for colony PCR, we picked 4 colonies for each construct - two colonies from LB + antibiotic 100μ plate, one colony from LB + antibiotic 10μ plate and one colony from LB + antibiotic + arabinose 100μ plate.


Colony PCR

We conducted colony PCR of E.coli transformed with GA13 and GA14 constructs in order to confirm successful assembly of these plasmids.

  • We prepared overnight liquid cultures of transformants - GA13 in LB + ampicillin medium, and GA14 in LB + kanamycin medium.
  • We performed colony PCR using Taq polymerase according to the following protocol, but we did not include any positive control. We used standard VR and VF2 primers, as indicated on the diagrams below:
Cam igem-GA13-diagnostic(I).jpg
Expected lengths of products:
GA13 insert ~3520 bp
GA14 insert ~3520 bp
  • Time profile used in the PCR machine was the following:
Hold 1 95°C 6 min
Cycling ×30 Denaturing 98°C 10 s
Annealing 55°C 30 s
Elongation 72°C 180 s
Hold 2 72°C 5 min
  • We obtained distinct bright bands on all lanes loaded with products of colony PCR, and their position on the gel corresponds to the predicted sizes of these DNA fragments. This suggests that these colonies carried correctly assembled plasmids. Therefore, we decided to extract plasmids from and prepare glycerol stocks of successful transformants.
The order of samples: Hyperladder I, GA13d-1, GA13d-1, HyperLadder I, GA13d-2, GA13d-3, GA13d-4, GA14d-1, GA14d-2, GA14d-3 and GA14d-4.


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