Difference between revisions of "Team:Edinburgh UG/Results"

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               <h2 style="text-align:left">UV Production Method</h2>
 
               <h2 style="text-align:left">UV Production Method</h2>
 
             <p style="text-align:left">We first started by looking at the <i>Escherichia coli</i> strains DH5-alpha (<i>recA<sup>-</sup></i>, <i>uvrA<sup>+</sup></i>) and CSR603 (<i>recA<sup>-</sup></i>, <i>uvrA<sup>-</sup></i>). It was found that when attempting maxicell formation in strains with functional uvrA, such as DH5-aplha, all stages post-UV exposure until the end of a 15-18 hour incubation must be carried out in complete darkness, to prevent photoreactivation by the UVR system. We also found that while CSR603 is a more efficient maxicell producer than DH5-alpha, it grows slower and the cells are significantly shorter in length and diameter than DH5-a. We surmised that this was because the cells are, in essence, sicker due to the mutations in DNA repair systems. When cultured in LB and exposed to 40 seconds of UV and then incubated for a further 18 hours, 70.0% CSR603 showed no DAPI fluorescence. When grown under the same conditions but exposed to no UV, 2.9% CSR603 showed no DAPI fluorescence.</p>
 
             <p style="text-align:left">We first started by looking at the <i>Escherichia coli</i> strains DH5-alpha (<i>recA<sup>-</sup></i>, <i>uvrA<sup>+</sup></i>) and CSR603 (<i>recA<sup>-</sup></i>, <i>uvrA<sup>-</sup></i>). It was found that when attempting maxicell formation in strains with functional uvrA, such as DH5-aplha, all stages post-UV exposure until the end of a 15-18 hour incubation must be carried out in complete darkness, to prevent photoreactivation by the UVR system. We also found that while CSR603 is a more efficient maxicell producer than DH5-alpha, it grows slower and the cells are significantly shorter in length and diameter than DH5-a. We surmised that this was because the cells are, in essence, sicker due to the mutations in DNA repair systems. When cultured in LB and exposed to 40 seconds of UV and then incubated for a further 18 hours, 70.0% CSR603 showed no DAPI fluorescence. When grown under the same conditions but exposed to no UV, 2.9% CSR603 showed no DAPI fluorescence.</p>
             <p style="text-align:left">Next, we used the <i>E. coli</i> strain MC4100 to produce a <i>recA</i>, <i>uvrA</i> knockdown, as this strain was recommended in literature for maxicell production. Through utilisation of RNA interference by MicC sRNAs, we created a <i>recA</i>, <i>uvrA</i> knockdown construct. The objective was twofold: to develop a method of maxicell production which could be theoretically applied to any strain of E. coli; and to create a healthier maxicell producing strain - after it was observed that CSR603 has impaired growth due to its sickness. Both of these objectives were successful. For the knockdown strain, we found that the colony forming units per mL culture 18 hours post UV-exposure was vastly lower than that of MG1655 (fully functioning <i>recA</i> and <i>uvrA</i>), and only slightly higher than CSR603 (fully non-functioning <i>recA</i> and <i>uvrA</i>). Furthermore, MC4100 growth rate in LB media and M9 glucose media is vastly higher than that of CSR603. When cells are cultured in M9 glucose media, there is no significant difference in CFU/mL 18 hours post-UV exposure when cells are exposed to light or kept in complete darkness. When cells are cultured in LB media, CFU/mL is significantly higher if the post-UV culture is exposed to light.</p>
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             <p style="text-align:left">Next, we used the <i>E. coli</i> strain MC4100 to produce a <i>recA</i>, <i>uvrA</i> knockdown, as this strain was recommended in literature for maxicell production. Through utilisation of RNA interference by MicC sRNAs, we created a <i>recA</i>, <i>uvrA</i> knockdown construct. The objective was twofold: to develop a method of maxicell production which could be theoretically applied to any strain of E. coli; and to create a healthier maxicell producing strain - after it was observed that CSR603 has impaired growth due to its sickness. Both of these objectives were successful. For the knockdown strain, we found that the colony forming units per mL culture 18 hours post UV-exposure was vastly lower than that of MG1655 (fully functioning <i>recA</i> and <i>uvrA</i>), and only slightly higher than CSR603 (fully non-functioning <i>recA</i> and <i>uvrA</i>) (Figure 1.). Furthermore, MC4100 growth rate in LB media and M9 glucose media (Figure 2.) is vastly higher than that of CSR603. When cells are cultured in M9 glucose media, there is no significant difference in CFU/mL 18 hours post-UV exposure when cells are exposed to light or kept in complete darkness. When cells are cultured in LB media, CFU/mL is significantly higher if the post-UV culture is exposed to light.</p>
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            <figure class="figure">
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  <img src="https://static.igem.org/mediawiki/2018/a/a2/T--Edinburgh_UG--strains.jpeg" class="figure-img img-fluid rounded">
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  <figcaption class="figure-caption">Figure 1. </figcaption>
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</figure>
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            <figure class="figure">
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  <img src="https://static.igem.org/mediawiki/2018/b/bc/T--Edinburgh_UG--4100lightdark.jpeg" class="figure-img img-fluid rounded">
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  <figcaption class="figure-caption">Figure 2. </figcaption>
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             <p style="text-align:left">The MicC constructs we produced were as follows:</p>
 
             <p style="text-align:left">The MicC constructs we produced were as follows:</p>
 
               <ul><li style="text-align:left"><a href="http://parts.igem.org/Part:BBa_K2725006">BBa_K2725006</a>: micC construct for recA knock down</li>  
 
               <ul><li style="text-align:left"><a href="http://parts.igem.org/Part:BBa_K2725006">BBa_K2725006</a>: micC construct for recA knock down</li>  

Revision as of 23:10, 17 October 2018

Edinburgh iGEM 2018

Results

Achievements

  • We have characterised various methods of maxicell production, to optimise their manufacture for synthetic biology
  • The active time frame of maxicells was quantified, to determine their potential “lifespan”
  • We have created parts which facilitate maxicell production in any E. coli strain of your choosing
  • We have introduced a functional biosensor into the maxicell chassis, which has shown that maxicells have the potential for gene expression for at least 18 hours after their production
  • Various methods of preventing horizontal gene transfer were explored, to increase the security of maxicells as a chassis designed for environmental release
  • Triclosan resistance was introduced into a standard backbone as an alternative to antibiotic selection, which would prevent the unwanted release of antibiotic resistance genes

Evaluating and Optimising Maxicell Protocols

Three methods of maxicell production were evaluated to identify the most efficient process. Each method causes a double-strand break in the chromosome, leading to its degradation by native exonucleases (the rec system, in recA knockout cells). After maxicell induction, all of these methods involved treatment by cycloserine to kill the non-maxicells. Cycloserine is an antibiotic that targets cell wall synthesis, thereby killing any actively dividing cells. The level of maxicell production was determined by fluorescence microscopy of samples stained with DAPI; a fluorescent stain that binds to double stranded DNA.

UV Production Method

We first started by looking at the Escherichia coli strains DH5-alpha (recA-, uvrA+) and CSR603 (recA-, uvrA-). It was found that when attempting maxicell formation in strains with functional uvrA, such as DH5-aplha, all stages post-UV exposure until the end of a 15-18 hour incubation must be carried out in complete darkness, to prevent photoreactivation by the UVR system. We also found that while CSR603 is a more efficient maxicell producer than DH5-alpha, it grows slower and the cells are significantly shorter in length and diameter than DH5-a. We surmised that this was because the cells are, in essence, sicker due to the mutations in DNA repair systems. When cultured in LB and exposed to 40 seconds of UV and then incubated for a further 18 hours, 70.0% CSR603 showed no DAPI fluorescence. When grown under the same conditions but exposed to no UV, 2.9% CSR603 showed no DAPI fluorescence.

Next, we used the E. coli strain MC4100 to produce a recA, uvrA knockdown, as this strain was recommended in literature for maxicell production. Through utilisation of RNA interference by MicC sRNAs, we created a recA, uvrA knockdown construct. The objective was twofold: to develop a method of maxicell production which could be theoretically applied to any strain of E. coli; and to create a healthier maxicell producing strain - after it was observed that CSR603 has impaired growth due to its sickness. Both of these objectives were successful. For the knockdown strain, we found that the colony forming units per mL culture 18 hours post UV-exposure was vastly lower than that of MG1655 (fully functioning recA and uvrA), and only slightly higher than CSR603 (fully non-functioning recA and uvrA) (Figure 1.). Furthermore, MC4100 growth rate in LB media and M9 glucose media (Figure 2.) is vastly higher than that of CSR603. When cells are cultured in M9 glucose media, there is no significant difference in CFU/mL 18 hours post-UV exposure when cells are exposed to light or kept in complete darkness. When cells are cultured in LB media, CFU/mL is significantly higher if the post-UV culture is exposed to light.

Figure 1.
Figure 2.

The MicC constructs we produced were as follows:

  • BBa_K2725006: micC construct for recA knock down
  • BBa_K2725007: micC construct for uvrA knock down
  • BBa_K2725008: micC construct for uvrA and recA knock down
  • BBa_K2725009: micC construct for the mCherry gene that produces increased mCherry fluorescence

Palindromic Cleavage Method

Another method of maxicell induction that was investigated involved using a strain of E. coli, DL3355 ( lacIq lacZχ- ParaBAD-sbcDC lacZ::pal460 recA::Cm), which contains a palindromic site in the chromosome that forms a hairpin loop. This hairpin loop can be cut by an sbcCD exonuclease that was introduced to the chromosome under control of an arabinose-sensitive promoter. This causes a double strand break in the chromosome. leading to digestion by native exonucleases. However, this method was found to be largely unsuccessful: a spot test of E. coli DL3355 with the sbcCD exonuclease gene under an arabinose inducible promoter inserted into the chromosome showed that there was no decrease in colony forming units after sbcCD induction. It was surmised that this was due to a high rate of mutation in this strain, as the palindromic sequence is a burden on the cell there is an inherent rate of loss of the palindrome site of 1/10000 per genome per generation. The rate of strain reversion is therefore very high, so this method of maxicell production is inefficient and not recommended.

Homing Endonuclease Method

The last method we looked at centres around E. coli DL2524 (MG1655 recA::CmR araB::PBAD-I-SceI lacZ::I-SceIcs fnr-267), a strain that contains in its chromosome an 18 base pair recognition site for the homing endonuclease I-SceI, and the I-SceI gene under control of an arabinose-sensitive promoter. Maxicell production by this strain was initiated by culturing in arabinose, which activates I-SceI expression, leading to a double-strand break in the chromosome at the I-SceI recognition site. This method was the most successful at maxicell production: the lowest percentage of cells seen to be fluorescing with DAPI were in DL2524 arabinose induced samples (compared to all UV induced maximal methods and DL3355).

Quantifying Maxicell Timeframe

ATP Quantification

Protein Retention

Next, we decided to investigate the level of protein degradation in our maxicells, to find out whether or not all the cellular machinery remains intact over long periods of time. To do so, we took samples of maxicells stored 4°C for 0 h and 24 h, and at 25°C & 37°C for 0 h, 24 h and 48 h. We then ran these samples through an SDS-PAGE gel, the results of which can be seen in figure (1) below. These results show that there is no major decrease in protein concentration within maxicells over a period of 48 h, not even at 37°C, suggesting that the level of protein degradation is minimal. Although we cannot determine absolute protein concentrations between the samples due to potential differences in sample preparation, we can see that they are not orders of magnitude different. It can therefore be inferred that protein degradation within maxicells is not a significant factor for their functionality over long periods of time.

Figure 1. SDS Page of All Maxicell Proteins Over Time when Stored at Different Tempratures. (see experiments page for details)

Functional Gene Expression

Finally, CSR603 UV-induced maxicells were used to investigate the ability of maxicells to transcribe and translate a chosen gene, in this case mCherry under an inducible arabinose promoter (BBa_K2725010). These maxicells were induced by arabinose to produce mCherry 18-25 hours after UV exposure. Fluorescence by mCherry was observed after arabinose treatment 24 hours after each sample was induced. The proportion of cells fluorescing that were induced 18 hours after UV exposure was 57.9%, which significantly decreases to 4.7% in samples induced 20 hours after UV exposure, and a maximum of 6% of cells fluorescing was seen in samples induced 25 hours post-UV exposure. In contrast, it was found that cells with intact chromosomes fluoresce only faintly after arabinose treatment, and mCherry is not visible to the naked eye in colonies cultured on LB+arabinose plates. It can be surmised, therefore, that maxicells can be induced to produce a gene product after their production, and can act as a biosensor: for arabinose in this case.

Unfortunately, due to difficulties in transformation of CSR603 we were unable to transform our ars-mCherry construct (BBa_K2725011) into this strain. This made it impossible to test the ability of maxicells to act as a biosensor for arsenic.

The Triple Lock System

Colicin Kill Switch

The results for the modelling section of our colicin kill switch can be seen here. We collaborated with Team Vilnius to develop a protocol for applying this model.

Semantic Containment

Our aim was to recode the kanamycin resistance gene with differing numbers of serine codons replaced with amber codons (1, 2, 5 and 10). E. coli TOP 10 was transformed with each of these 4 plasmids and their growth measured on 8 concentrations of kanamycin - concentrations decreasing 2 fold from 400 ug/mL to 3.125 ug/mL. The outcome of this can be seen in Figure 2, which shows that replacing a single serine codon with an amber STOP codon does not fully inhibit kanamycin resistance in this strain. The fact that 1* showed growth on kanamycin is due to an inherent level of amber suppression. This phenomenon has been investigated by in silico modelling to determine the rates of read-through for the different numbers of mutations.

Figure 2. Growth curves of Top10 E.coli transformed with P1003, P1003* (1*), P1003** (2*), P1003 5* (5*) and P1003 10* (10*) grown in the given concentration of kanamycin. These growth curves show the extent of kanamycin resistance conferred by each part.

After it was determined that sufficient kanamycin resistance could not be conferred by the 2*, 5* (BBa_K2725012) and 10* (BBa_K2725013) genes when supD is functional, we then sought to test for resistance when supD is mutated as an amber suppressor. We also tested the extent of kanamycin resistance when the amber suppressor supD was expressed under different strength Anderson promoters. The results of this can be seen in Figure 3 below.

Figure 2. Growth curves of 8 Top10 E.coli double transformants in the given concentration of kanamycin . These growth curves show the extent of kanamycin resistance conferred by each part combination.

It is clear that when the amber suppressor supD is expressed under medium strength promoter J23108, P1003 with 1, 2, and 5 amber codons can be expressed at a sufficient enough level that confers kanamycin resistance. This means the rate of serine integration at amber codons is much higher than the removal of the nascent polypeptide by Release Factor 1. However, there was no kanamycin resistance conferred by the P1003 10* gene. This means that the amber suppressor supD was not expressed at a high enough level to outcompete Release Factor 1 at 10 successive amber STOP codons. We attempted higher level expression of amber suppressor supD (BBa_K2725014), however no double transformants with this part had any kanamycin resistance. We think this is due to the presence of amber STOP codons in the chromosome. If chromosomal genes that use amber STOP codons for termination of translation consistently have serine incorporated (and continued translation) instead, this would place a significant metabolic burden on the cell. This therefore generates significant selection pressure for a mutation that decreases the expression level of the amber suppressor supD or prevents it completely. Because the construct was under a constitutive promoter this mutation likely occurred before the cells were transferred to a kanamycin medium.

The Anderson Promoter-SupD constructs are as follows:

  • BBa_K2725014: Serine amber suppressor tRNA gene under J23102 Anderson promoter
  • BBa_K2725015: Serine amber suppressor tRNA gene under J23103 Anderson promoter
  • BBa_K2725016: Serine amber suppressor tRNA gene under J23108 Anderson promoter

Alternative Selection

FabI

The fabI gene was PCR amplified from DH5-α genomic DNA and the biobrick prefix and suffix was added. The PCR product was introduced into the biobrick site of pSB1C3. The FabI biobrick was then expressed under a high constitutive expression cassette (BBa_K314100) to produce BBa_K2725001 and growth was observed on triclosan at 1 µM (figure ____________), while untransformed DH5-alpha showed no growth (figure ____).

Figure_______: 1 µM triclosan agar plate, plated with E. coli DH5-alpha transformed with BBa_2725001
Figure_______: 1 µM triclosan agar plate, plated with untransformed E. coli DH5-alpha

FabV

As a proof of concept for our final design, the fabV gene was introduced into pSB1C3, replacing chloramphenicol resistance by Gibson Assembly to produce a new plasmid backbone: pSB1Tcs1. The fabV gene was therefore expressed under the chloramphenicol acetyltransferase promoter and ribosome binding site. This new plasmid conferred resistance to triclosan above 16 mM, showing similar growth profiles at all concentrations below 16 mM, while the growth of untransformed DH5-α was inhibited at 16nM and was severely inhibited above 4 µM (figure __________). It is therefore advised that 4-16 µM triclosan be used for selection in liquid culture. However, It was found that 1 µM triclosan is sufficient for selection on agar plates, with no colonies being observed when untransformed DH5-ɑ was plated at 1 µM (figure _________), as lower concentrations can be used for selection when plating.

The fabV gene was then PCR amplified from our pSB1Tr1 plasmid to add the Biobrick prefix and suffix. This fabV Biobrick (BBa_K2725002) was inserted after a high constitutive expression cassette (BBa_K314100) to produce BBa_K2725003 and a low constitutive expression cassette (BBa_K314101) to produce BBa_K2725004, both of which showed growth on triclosan at 1 µM (figure ______).

1 µM triclosan agar plates, plated with E. coli DH5-alpha transformed with BBa_2725003 (left) and BBa_K2725004 (right)

What's Next?

  • The triclosan resistant backbone should be recoded to replace all serine codons with amber stop codons, so that it is compatible with the semantic containment system
  • Triclosan resistance is due to a higher than normal expression of Fab proteins, or more specifically, it is due to an increased number of triclosan binding sites. It may therefore be possible to decrease the metabolic burden on the cell or increase resistance by trimming the FabI or FabV protein down to just the domain which binds to triclosan. This would further optimise this system of triclosan resistance

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