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Revision as of 03:22, 17 October 2018


Results

Building and Testing Pixcell Constructs

Assembling the Pixcell Constructs

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Description

The PixCell Construct consists of a repurposed version of the soxRS regulon from E. coli, consisting of SoxR and GFP being expressed from either side of the pSoxR/pSoxS bidirectional promoter. pSoxR provides constitutive expression of SoxR. When oxidised, either directly by redox-cycling molecule or by oxidative stress, SoxR binds and activates transcription of GFP downstream of pSoxS.

Figure 1. Illustration of the PixCell Construct

Relevance

The Pixcell construct was designed to test whether we could control the expression of GFP by controlling the oxidation state of SoxR through our electrochemical set up.

Results

Using the Golden Gate assembly method, with two inserts; the SOXRS regulon and GFP, which were originally amplified out from the E. coli genome and a storage vector respectively, the construct was assembled. Gel electrophoresis showed that a construct of approximately the right length was produced and the construct was then sequence verified.

Figure 1. PCR results from the amplification of the entire construct

In order to lower the basal level of GFP expression a degradation tag was added. Therefore, any increase in GFP expression induced by the oxidation of SoxR would be more predominant.

Figure 1. Illustration of the PixCell Construct DegTag

Summary

The Pixcell construct enables us to test whether we can control gene expression by controlling the oxidation state of soxR. The Pixcell construct DegTag enables the system to be more dynamic in that seeing the system switch from on to off is quicker.

Characterizing Pixcell Constructs

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Description

We characterised the PixCell circuits in a series of steps in order to make them respond to an electronic input. In order to demonstrate if the PixCell construct is responsive to oxidation signals, we started by chemically inducing the circuit with oxidised pyocyanin in solution, as at the time we did not have an electrode setup that would work aerobically in solid cultures. Characterization experiments were performed by measuring cell growth and GFP expression at a range of increasing pyocyanin, ferricyanide and ferrocyanide concentrations, as fully described in the “Methods” section.

Relevance

These results demonstrate that the assembled PixCell circuit can be switched on by oxidative signals and switched off by reductive signals. These experimental data were also handed over the dry lab, where information about fold induction and degradation rates supported and further implemented the theoretical models.

Results

As a first step, we investigated the effect of oxidised pyocyanin on cell health. We observed that pyocyanin concentrations higher than 10 uM significantly impacted cell health (figure 1). We then measured GFP expression at a range of different concentrations (figure 2). We found an optimal trade-off between cell health and GFP expression at a concentration of 2.5 uM, which is half of that used by (Tschirhart et al., 2017) in their anaerobic system (figure 3). We hypothesised that a reason for this lower concentration might be because in our aerobic system less oxidising input is required. Once identified our working pyocyanin concentration, that is the cellular redox-odulator, we varied the concentration of ferro/ferricyanide, the redox-modulators at the electrode interface, to find an optimal redox balance between pyocyanin and the reduced and oxidised forms of FCN (figure 5, 6, 7, 8) . As above, we investigated the effect of the redox molecules on cell health and identified the a FCN concentration (10 mM), which provided optimal balance between GFP expression and cell health.

Figure 1.Looking for optimal pyocyanin concentration on cell viability

Figure 2.Ferricyanide dose response

Figure 2.Ferricyanide dose response

Figure 2.Ferricyanide dose response

Figure 2.Ferricyanide dose response

Figure 2.Ferricyanide dose response

Figure 2.Ferricyanide dose response

Figure 3.Ferrocyanide dose response

Explain results here.

Summary

These experiments allowed us to demonstrate that our constructs are responsive to oxidising input and enabled us to identify the concentrations of redox-molecule. These informations enabled us to formulate the chemical compositions for the next experiments in aerobic solid cultures.

Electrochemistry of Redox Modulators

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Description

To demonstrate the ability of our electrode set-up to selectively oxidise and reduce our redox modulators in solution, we investigated the redox status of the our redox modulators with cyclic voltammetry (CV) and by measuring the absorbance at 390 nm with a plate reader. CV data showed that a voltage of +0.5 at the working electrode enables bulk oxidation, whereas a voltage of -0.4 allows bulk reduction. However, the presence of oxygen in aerobic environments interferes with the oxidation signal carried by the electrodes. Measuing optical absorbance at 390 nm with a plate reader, we then investigated the redox kinetics of pyocyanin in the presence of the reducing agent sodium sulfite.

Relevance

These results show that our set-up is able to selectively and reversibly oxidise and reduce our redox modulators. Furthermore , by performing these electrochemistry experiments, we proved that addition of the reducing agent sodium sulfite enables complete chemical reduction of the system, even in aerobic environment.

Results

Cyclic Voltammetry was performed using a multichannel potentiostat connected to a computer. Reaction kinetics were performed using a FLUOstar BG Labtech plate reader, as describes in the “Methods” section.



Figure 1. Square-wave voltammetry setup



Figure 2. Square-wave voltammetry of redox modulator



The graphs above summarise the results showing that our system was consistently bulk reduced at -0.3V and bulk oxidised at +0.5V. The addition of Sulfite and cell containing the pixCell construct did not significantly alter the reduction and oxidation profile. These results led us to chose +0.5V as our oxidising potential in the following experiments testing the spatial electronic control of gene induction.



Figure 3. Amperometry of the final plate conditions



Figure 4. Pyocyanin reduction by the reducing agent Sodium Sulfite

In order to chemically reduce our system, we added sodium sulfite as a reducing agent. We measured the concentration of oxidised pyocyanin in solutions with increasing sulfite concentration. As expected, the more sulphite added, the less absorption at 390 nm occurs (peak for oxidised pyocyanin). However this linear relationhiop resulted to be true only up to ca. 5% of sulphite. After that point it seems that an oxidised species is being produced.

Figure 5.Production of Pyocyanin Sulfonate at 2.5% Sulfite

To dig deeper into the reasons of the unexpected non-linear relationship described above, we played with lower sulfite concentration. After searching in the literature (Glasser, 2017), we hypothesised that sulfite could react with pyocyanin, producing pyocyanin sultanate. because pyocyanin sulfonate has an absorption peak at 400 nm, we performed the same experiment as above but this time measuring the OD at both 390 and 400 nm. We found that at a concentration of 2.5 % of sulfite, there is appear of absorption at 400 nm, suggesting that pyocyanin sultanate is being produced. Because pyocyanin sulfonate is toxic to cells, , we carried the next experiments with lower sulfite concentration.



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Summary

These results describe the first ever aerobic electrogenetic control system, that works both in liquid and solid E. coli cultures.

Spatial Electronic Control of Gene Induction

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Description

Here we demonstrated the first spatial activation of gene expression using electronic control.

Relevance

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Results

An electrode rig was set up to apply these potentials to cells grown on an agar plate containing the final reaction condition of 2.5μM pyocyanin, 0.02% sodium sulfite and 10mM ferrocyanide. Redox reactions only occur at the electrode surface during an electrochemistry experiment, meaning that oxidised pyocyanin and ferrocyanide were only produced in close proximity to the working electrode upon the application of a +0.5V pulse. Fluorescence images of agar plates clearly show localised expression of GFP around the electrode. This not only shows that the device allows for electronic control of gene expression, but also demonstrates high spatial control meaning it can be used for programmable spatial patterning of cell populations.



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Summary

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Building and Characterizing the Pixcell Library

Creating the Sox Library

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Description

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Relevance

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Results

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Figure 1. PCR results of genomic extraction of SoxR from E. coli (including bi-directional promoter and SoxR protein gene)

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Summary

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Characterising the Sox Library

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Description

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Relevance

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Results

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Figure 1. PCR results of genomic extraction of SoxR from E. coli (including bi-directional promoter and SoxR protein gene)

Lorem ipsum dolor sit, amet consectetur adipisicing elit. Excepturi, nisi illum. Consequuntur cum, sequi quo, esse facere corrupti voluptatum ipsum vel consequatur error quasi tenetur, repellat voluptatibus aspernatur optio mollitia! Lorem ipsum dolor sit, amet consectetur adipisicing elit. Excepturi, nisi illum. Consequuntur cum, sequi quo, esse facere corrupti voluptatum ipsum vel consequatur error quasi tenetur, repellat voluptatibus aspernatur optio mollitia!

Summary

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Testing Alternative Non-toxic Redox Modulators

Testing Phenazine Methosulfate

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Description

Our electrogenetic control system relies on the electron carrying action of the redox-cycling drug pyocyanin, which is toxic metabolite from synthesised by Pseudomonas aeruginosa. This poses limitations to our system, with regards to safety and possible applications. Therefore, we searched in the literature for alternative SoxR inducers and and tested potential non-toxic alternatives. Shown below are the characterization data for the best candidate alternative: phenazine, methosulfate.

Relevance

These results demonstrate the first ever use of PMS as an electrogenetic inducer.

Results

The above setup was used to perform Sqaure-wave voltammetry confirming that ferrocyanide was bulk reduced at -0.3V and bulk oxidised at +0.5V.



Figure 1. Phenazine as as Cheaper, Non-toxic Redox Modulator

This working concentration provided an X-fold increase in GFP expression. Previous research suggests this response could be improved ~10-fold further by supplementing the growth media with branched-chain amino acids, the synthesis of which is inhibited by PMS leading to cell death.

Summary

These results demonstrates the SoxR/pSoxS system that we devised, can be used a non-toxic and effective tool for chemical, as well as electronic, gene induction. PMS is also incredibly cheap, being 40,000x cheaper than pyocyanin, ~190x cheaper than arabinose and ~29x cheaper than aTc per reaction.

Applications

Biocontainment- Gp2 Growth Inhibition

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Description

We used the Gp2 toxin to create an electrogenetic device for biocontainment applications. Electronic activation of the SoxR/pSoxS transcription factor - promoter couple can inhibit cell growth by inducing expression of Gp2, a T7 phage-derived RNA polymerase inhibitor. The construct was assembled into a plasmid with a low-copy number pSC101 origin of replication to reduce the effect of promoter leakiness impacting on cell growth.

Relevance

These results serve as proof of concepts for the biocontainment application, as described in the “Applications” sections

Results

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Figure 2.Negative controls



Figure 2.Negative controls



Figure 2.Negative controls

Explain results here.

Summary

With some improvement, and when used in combination with the PixCell electrode array, this biocontainment device could be used for biocontainment of GMOs in contained-use devices. This is analogous to how electric fences can be used to restrain livestock.

Fabric Bioprinting - Melanin

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Description

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Relevance

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Results

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Figure 1. PCR results of genomic extraction of SoxR from E. coli (including bi-directional promoter and SoxR protein gene)

Lorem ipsum dolor sit, amet consectetur adipisicing elit. Excepturi, nisi illum. Consequuntur cum, sequi quo, esse facere corrupti voluptatum ipsum vel consequatur error quasi tenetur, repellat voluptatibus aspernatur optio mollitia! Lorem ipsum dolor sit, amet consectetur adipisicing elit. Excepturi, nisi illum. Consequuntur cum, sequi quo, esse facere corrupti voluptatum ipsum vel consequatur error quasi tenetur, repellat voluptatibus aspernatur optio mollitia!

Summary

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