Template:IONIS Paris/Project/Optogenetics
What is Optogenetics?
Sensing light
Nature has evolved a multiple of photoreceptors able to sense light. Those systems have provide synthetic biology tools for the precise control of biological functions, offering superior spatial and temporal resolution. The research field focusing on the combination of optical method and genetic has been named «optogenetics» and can lead to the control of gene expression, cell morphology or even signaling pathway thank to light signal.
Photoreceptors
What is VVD and how does it work?
Among other photoreceptors, Vivid (VVD) is the smallest known Light–oxygen–voltage (LOV) domain protein and photo-inducible dimer. Isolated from Neurospora crassa, VVD forms a homo-dimer in response to a blue-light stimulus. The LOV domain, present in VVD, are small blue-light sensing domains found in prokaryote, fungi and plants. After blue-light activation, a covalent bond is formed between the co-factor Flavin mononucleotide (FMN) and one of the cysteine residue. This bond leads to conformational change inducing functions by dissociating the C-terminal a-helix (Ja) and the LOV-core. In VVD, this undock trigger homodimerization.
Why did we choose the photoreceptor VVD ?
Contrary to other photoreceptors, VVD is a small protein with 150 amino-acids facilitating accurate molecular design and avoiding steric issue. Moreover, it is a homo-dimer when most of photo-inducible dimer are heterodimer. In addition, the use of VVD is easy; and doesn’t need any addition of co-factors: VVD works with Flavin adenine dinucleotide (FAD) which is already abundant in eukaryote and prokaryote cells.
Split-Protein
What is a split-protein and how does it work?
A split protein is a protein whose sequence has been divided into two (or more) different parts. Often used to study protein-protein interaction, the protein can not perform its function until the parts are put back together. For instance, YFP, the yellow-fluorescent protein that we are willing to produce in our engineered bacteria, will only express fluorescence when its two part will be reunited.
Why did we choose a split-protein?
In normal condition, the production of a protein in response to a stimulus can easily reached several hours due to the many step required for the protein synthesis. By using split-protein, we are taking advantage of the absence of fluorescence when the two parts are apart. Indeed, the two parts of our split-YFP, when remaining separated, can be produced without being effective. Therefore, the overall process is far less time-consuming. However, to implement a light control on the fluorescence activation, a genetic construction gathering the VVD photoreceptor and our split-YFP have to be engineered.
Biomolecular fluorescence complementation
The new alternative approach for the visualization of protein interaction have been developed; the biomolecular fluorescence complementation (BiFC) techniques based on the complementation between fragments of fluorescence proteins; fragments of the yellow fluorescent protein (YFP) brought together by the association of two interaction partners fused to the fragments. They noticed that the spectral characteristics of BiFC of YFP were virtually identical to those of intact YFP.
Kill switch
What is a kill switch?
A kill switch is a genetically-encoded suicide trigger. This trigger can be a change in the environment which will make the organism’s life dependent on it. In our project, the change will be the presence or not of light. That is very interesting as we could create a game over in our Bio Console, once we trigger the bacteria’s death through light. Moreover, our team is really concerned about BioSafety. It is important for us to avoid any possibility of escaping from our microfluidic chip. The Kill switch would permit to contain our genetically modified bacteria into the chip through lethality.
A photosensible system: the pDawn and pDusk plasmids
How do they work?
After reading many papers to select an appropriate light-sensing system to use for the kill switch, our team came across the pDawn and pDusk plasmid. Those plasmids employ bluelight photoreceptors to confer light-repressed or light-induced gene expression in with up to 460-fold induction upon illumination. Controlled by this system, we thought to add toxins in it to kill our bacteria whenever we want.
They are not dependent on nonnative chromophores that are often supplied exogenously and do not need any introduction of cofactor-synthesis genes. Moreover, they are practical to use since current optogenetic tools require multiple plasmid components.
Finally, they deal with many limitations in a one-plasmid system which is based on the YF1/FixJ system.
The plasmids pDusk for light repressed and pDawn for light-activated gene expression. In pDusk, the YF1/FixJ drives gene expression from the pFixK2 promoter in a blue-light repressed manner. When we insert the λ phage repressor cI and the λ promoter pR in pDawn, this will invert the signal polarity and lead to the gene expression.
The histidine kinase YF1 employs a light oxygen voltage blue light photosensor domain. In the absence of blue light, YF1 phosphorylate the regulator FixJ which induces gene expression from the FixK2 promoter. The opposite happens with pDawn. We obtain the plasmids from the Centre for Biological Signalling Studies and the University of Freiburg. As soon as we received them, we observed that the multiple cloning site as well as the λ promoter pR were located upstream the YF1/FixY system.
Why did we choose them?
One of the most important point in iGEM requirement is to use Biobrick that have been created by other teams and that have been characterized. We have chosen those protein complex in our kill-switch mainly because this complex correspond to the better characterized BioBrick(BBa_K124003) with toxins and the most efficient with relevant results.
pDawn & pDusk - Toxin systems
So we aim to construct an efficient kill-switch triggering by light. In this way we will construct two different parts. The first one will be composed of pDawn and holin/endolysin. Toxins will be produced after light stimulation and induce lysis. The second part will be composed of pDusk and endolysin/holin complex, this will lead to the cell lysis when the bacteria won’t be exposed to light. This second part will be more difficult to characterized indeed all steps before characterization of the plasmid as plasmid amplification will have to be under light.
SAFETY
Our safety measures
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BIOBRICKS
Our parts of DNA
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MICROFLUIDICS
Our challenge in achieving the Bio-console
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