Team:Slovenia/TheSwitchPositiveFeedbackLoopSwitch

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Widder, S., Macía, J., and Solé, R. (2009) Monomeric Bistability and the Role of Autoloops in Gene Regulation. PLoS ONE 4, e5399.
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Cherry, J., L., Adler, F., R. (2000) How to make a Biological Switch. <i>J. Theor. Biol.</i> <b>203</b>, 117-133.
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Macía, J., Widder, S., Solé, R. (2009) Why are cellular switches Boolean? General conditions for multistable genetic circuits. J. Theor. Biol. 261, 126-135.  
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Macía, J., Widder, S., Solé, R. (2009) Why are cellular switches Boolean? General conditions for multistable genetic circuits. <i>J. Theor. Biol.</i> <b>261</b>, 126-135.  
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Cherry, J., L., Adler, F., R. (2000) How to make a Biological Switch. J. Theor. Biol. 203, 117-133.
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Widder, S., Macía, J., and Solé, R. (2009) Monomeric Bistability and the Role of Autoloops in Gene Regulation. <i>PLoS ONE</i> <b>4</b>, e5399.
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Revision as of 18:25, 26 September 2012


Positive feedback loop switch

We designed a bistable genetic toggle switch based on orthogonal TAL repressors and activators which is composed of a pair of mutual repressors and a pair of activators exending the classical toggle swith with positive feedback loops.

Simulations of the positive feedback loop switch demonstrated bistability even at low or no cooperativity.

Stochastic and deterministic simulations indicate higher robustness in comparison to the mutual repressor switch.

We experimentally tested the switch by monitoring production of two fluorescent protein reporters.

We confirmed a clear bimodal distribution of fluorescence and demonstrated adoption of stable states by induction with corresponding inducer molecules.

The switch persisted in a stable state after the removal of inducer molecules, which confirmed the epigenitc bistability of our system.

Bistable genetic switch based on non-cooperative elements

Mathematical analysis of genetic switches from the literature indicates that cooperativity, which introduces a nonlinear response, is required for a functional bistable switch, consisting of two mutual repressors (Cherry et al. 2000). Macia et al. (2009) and Widder et al. (2009) proposed that bistability could be introduced by non-cooperative elements, when nonlinearity is introduced if for example, protein A is able to repress transcription of protein B and at the same time activate its own transcription and vice versa (Figure 1).

Figure 1. Macia et al. (2009) and Widder et al. (2009) proposed a mathematical solution for creation of a bistable switch that does not require cooperative binding of transcriptional regulators. According to the proposed model, transcription factor A should activate its own transcription and repress the transcription of gene B and vice versa.



We, as molecular biologists, do not know of any protein acting simultaneously as a repressor and activator, therefore we were not surprised that to our knowledge, this type of a bistable switch has not yet been experimentally implemented. However, we realized that the ability to design TAL repressors and activators directed against the same binding site could offer a solution to this problem and provide a unique opportunity to construct orthogonal bistable switches based on noncooperative elements.




Results

Design

We designed an upgraded mutual repressor switch, where we introduced two additional positive feedback loops (Figure 2), consisting of two TAL activators targeted against the same binding site as the pair of opposing TAL repressors. In other words, rather than having the same protein function as an activator and repressor, we used two proteins, competing for the same operator. The same binding sequence for the activator and repressor introduced competition for the binding site and introduced the nonlinearity required for the bistability. For the purpose of our iGEM project, we designed a bistable switch with a positive feedback loop, capable of switching between the two states through regulation by inducer molecules (Figure 3).

Modeling

Before embarking on to the experimental verification, we performed a thorough modeling analysis of the designed switch. We incorporated parameters, obtained from the repression and activation experimental results into our simulations. Both deterministic and stochastic simulations demonstrate that the positive feedback loop switch is significantly more stable than the mutual repressor switch without the positive feedback loops. Most importantly, even without cooperativity, the system exhibits bistability (Figure 4). This switch is also more robust despite leaky expression of transcription factors, which caused the simple mutual repressor switch to exhibit no stability at all without cooperativity.


Experimental testing of the bistability of the switch

Figure 5. Functional components (operons and inducers) of the positive feedback loop switch. .

For experimental implementation of the positive feedback loop toggle switch we introduced the following components into cells (Figure 5):
  • a pair of TAL:KRAB repressors (TALA and TALB), controlled by the opposite TAL (TALA controls the transcription of TALB and TALB controls the transcription of TALA), exactly as in the classical toggle switch
  • a pair of TAL:VP16 activators (TALA and TALB), each activating its own transcription and transcription of the opposite TAL repressor
  • two of the constructs were tagged with fluorescent reporter proteins (BFP and mCitrine) via a t2A sequence, which ensured the equimolar production of the fluorescent reporter and TAL regulator
  • Both TAL repressor and activator pairs (A and B), controlled by inducible repressors
  • Constitutively expressed inducible repressor constructs
  • Inducer molecules (pristinamycin and erythromycin)


We analysed the performance of the switch by using two fluorescent proteins with good spectral separation (BFP and mCitrine), which enabled easy detection and quantification by confocal microscopy and flow cytometry.

To analyse the bistability we used flow cytometry, a technique which allowed us to detemine the number of cells expressing either one or both of the fluorescent reporter proteins. Although cells were transfected with the complete switch device including both reporters, the analysis of the cells demonstrated clear bimodal distribution - the majority of the analyzed nonstimulated cells expressed only one of the two fluorescent proteins, probably resulting from stochastic events or due to the a slight imbalance of the amount of transfected plasmids (Figure 6A). This bimodal distribution of fluorescence clearly demonstrates the intrinsic bistabilty of our system in comparison to the classical mutual repressor toggle switch topology, where a large fraction of cells expressed both fluorescent reporters. The addition of either one of the inducers switched the reporer production towards only one of the fluorescent proteins (Figures 6B and 6C).


Confocal microscopy confirmed the high expression of the expected and no expression of the opposite fluorescent protein in both induced states (Figure 7). This means the addition of an inducer shifts cells to a corresponding state which is preserved even when the inducer is removed (Figure 8). The system remained in a stable state several days after the removal of the signal, which confirms the bistability of our positive feedback loop switch.



References

Cherry, J., L., Adler, F., R. (2000) How to make a Biological Switch. J. Theor. Biol. 203, 117-133.

Macía, J., Widder, S., Solé, R. (2009) Why are cellular switches Boolean? General conditions for multistable genetic circuits. J. Theor. Biol. 261, 126-135.

Widder, S., Macía, J., and Solé, R. (2009) Monomeric Bistability and the Role of Autoloops in Gene Regulation. PLoS ONE 4, e5399.


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