Tokyo/Works/Future works

From 2007.igem.org

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<br>In this iGEM project, we have developed our model of E. coli.
<br>In this iGEM project, we have developed our model of E. coli.
The Wet and Dry approaches have demonstrated apparently interesting at the same time academically attracting results. Though these successive Wet and Dry approach and by employing other methods such as a single cell analysis, as mentioned above, we could achieve our model that behaves as we desigend. And through this process we could obtain synthetic biologically significant things.  
The Wet and Dry approaches have demonstrated apparently interesting at the same time academically attracting results. Though these successive Wet and Dry approach and by employing other methods such as a single cell analysis, as mentioned above, we could achieve our model that behaves as we desigend. And through this process we could obtain synthetic biologically significant things.  
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<br>In addition, our "genetically engineered machines" could...
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Consider the case where those two genes encode two different proteins of which concentrations should always remain at a certain ratio.
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It is even more convenient if the ratio can be kept only by adding a single set of the machines with the same genes. Regardless of the initial ratio of the two genes being expressed, the machines could change their expressing ways of the genes so that two states of the machines stably coexist. Since the ratio of the machines is kept the same, the ratio of the two expressed proteins would remain the same, though it might show slight oscillation.
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<br>
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In this way, our machine could be applied to biosynthesis of some chemical components and maintenance of the concentrations in solutions at a certain level.
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Furthermore, by improving the security and safety, the machines could be medically applied to our human bodies.  
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There are complex communities bacteria, producing necessary or harmful compounds for ourselves as well as themselves, in our bodies.  
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Our machines can be applied to some of these intestinal bacteria in order to properly regulate the communities and thereby the production of necessary compounds for us.
 +
<br>
 +
<br>
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Not limited to practical applications, we could also improve the machines so that their stable coexistence is maintained at a much higher or lower concentration, in a larger space, and during longer time course. 
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Or we could make the machine receive more than two inputs and the whole system stable under the coexistence of three or five different states of the machines.
 +
If we could improve our machines in this way, we could make our model closer to real ecosystems or bacterial communities in the nature.
 +
<be>
 +
<be>
 +
These are merely dream at this moment; however, the regulation of gene expression depending on the circumstances including other coexisting cells will be better engineered.

Revision as of 15:11, 26 October 2007


Works top  0.Hybrid promoter  1.Formulation  2.Assay1  3.Simulation  4.Assay2  5.Future works

Balancing gene expression

According to the simulation results, we have found that the relative strength of the promoters of both sides, or relative expression levels of the downstream genes should be changed in order to reach our model. It might be possible to get closer to our goal by extremely focusing on such Wet experiments undergoing a number of trial-and-errors. However, now that we have almost obtained the strong methods of Dry approaches that compensate Wet ones, we can employ even more sophisticated methods as we have done in this project. We have estimated based on the simulation what should be done next. One option is to change the ribosomal binding sites (RBS) to modulate largely expression level of the downstream genes. There are different RBS available as BioBrick parts, we could choose proper strength of RBS. Balancing the expression levels of both sides must be a great leap to our goal.

Single cell analysis with a cell sorter

Throughout the Wet experiments so far, we have observed our genetically engineered cells, not at an individual levels but at a collective level. With a single cell analysis, our simulation results would be more clearly confirmed.
We could do this at the next step by using a cell sorter, which separates a mixture of cells into individuals. Then we could observe which states, A, B, or unstable, individual cells are taking at the moment of the measurement and how many of them are in each state.


Adapters as a new BioBrick category

During the construction of genetic circuits, we often found the necessity of the gene insertion between already ligated genes as in the present work.


However, it is still difficult to exchange iGEM parts, which should be designed convenient for the construction, because iGEM parts have to be ligated laterally.


It is necessary for more convenient BioBrick construction
(1) to make room for parts insertion between genes after they are connected
(2) to connect genes processed by different restriction enzymes.


Here we suggest “adapters” to solve this inconvenience. In the present project, we have designed “adapters,” BioBrick parts that connect differently digested DNA, meeting the requirement (2).


Together with TokyoStandard, the BioBrick parts our last year’s team Tokyo Alligance developed to meet the requirement (1), we suggest a new category of “adapter” as shown in Fig. 1.


Fig. 1 The concept of adapters
Adapters will provide more convenient Biobrick-parts-construction methods.


In this iGEM project, we have developed our model of E. coli. The Wet and Dry approaches have demonstrated apparently interesting at the same time academically attracting results. Though these successive Wet and Dry approach and by employing other methods such as a single cell analysis, as mentioned above, we could achieve our model that behaves as we desigend. And through this process we could obtain synthetic biologically significant things.


Consider the case where those two genes encode two different proteins of which concentrations should always remain at a certain ratio. It is even more convenient if the ratio can be kept only by adding a single set of the machines with the same genes. Regardless of the initial ratio of the two genes being expressed, the machines could change their expressing ways of the genes so that two states of the machines stably coexist. Since the ratio of the machines is kept the same, the ratio of the two expressed proteins would remain the same, though it might show slight oscillation.
In this way, our machine could be applied to biosynthesis of some chemical components and maintenance of the concentrations in solutions at a certain level. Furthermore, by improving the security and safety, the machines could be medically applied to our human bodies. There are complex communities bacteria, producing necessary or harmful compounds for ourselves as well as themselves, in our bodies. Our machines can be applied to some of these intestinal bacteria in order to properly regulate the communities and thereby the production of necessary compounds for us.

Not limited to practical applications, we could also improve the machines so that their stable coexistence is maintained at a much higher or lower concentration, in a larger space, and during longer time course. Or we could make the machine receive more than two inputs and the whole system stable under the coexistence of three or five different states of the machines. If we could improve our machines in this way, we could make our model closer to real ecosystems or bacterial communities in the nature. <be> <be> These are merely dream at this moment; however, the regulation of gene expression depending on the circumstances including other coexisting cells will be better engineered.