Difference between revisions of "Team:Paris Saclay/Perspective"

(Production of non-GMO strains for the industry)
(Study the chromosome structure and function)
 
(35 intermediate revisions by 5 users not shown)
Line 1: Line 1:
 
{{Team:Paris_Saclay/project_header|titre=Perspective}}
 
{{Team:Paris_Saclay/project_header|titre=Perspective}}
 +
<html><style>header{background-image: url("https://static.igem.org/mediawiki/2016/8/8f/T--Paris_Saclay--banniere_project.jpg");}</style></html>
  
 
=Perspective=
 
=Perspective=
  
In this project we design a tool for study the relation of DNA structure and gene expression. Here in perspective we propose many applications of our tool in genome study and industry. Using dCas9 in this system give us this advantage to target the desired sequence specifically and change structure of DNA. Indeed, it would be possible to design specific sgRNA to target specific sequences.
+
In this project we design a tool to study the relation between DNA structure and gene expression. Here we propose many applications of our tool in genome study and industry. Using dCas9 in this system would give us the advantage to specifically target the desired sequence and change the structure of the DNA. Indeed, it would be possible to design specific sgRNA to target specific sequences.
  
 
=Study the chromosome structure and function=
 
=Study the chromosome structure and function=
  
Our tool considers as a reporter for chromosome structural properties. According to the Lagomarsino et al. paper developing a stable reporter is the most important challenge in chromosome structural studies. '' (Lagomarsino et al., 2015).
+
Our tool can be considered as a reporter for chromosome structural properties. According to Lagomarsino ''et al.'', developing a stable reporter is the most important challenge in chromosome structural studies. '' (Lagomarsino et al., 2015).
One of the classic technics to study the contact between two arbitrary genomic loci is protein-fragment complementation assay (PCA). In PCA assay two proteins of interest (targets) are genetically linked to two moieties of an enzyme (reporter) that can confer resistance to the bacterium. Because the reporter is fully assembled only when the two target proteins interact, the fraction of surviving bacteria after an antibiotic treatment provides quantitative information regarding the interaction energies between the two proteins. It is assumed that this assay may be naturally transposed to the problem of the contact between two genomic loci. Lagomarsino suggested in his paper that in order to end this problem, instead of considering two target proteins, they propose to consider a unique target that can recognize two genomic loci. For example, the CRISPR/Cas9 system with two different short sgRNAs could be used to direct the target, a modified Cas9 with no endonuclease property, to the genomic loci. The modified Cas9 would then be used in two different fused systems, each one containing one reporter moiety. <b>[Fig. 1]</b>.  In our project we chose tripartite split-GFP as a marker.
+
One of the classic technics to study the contact between two arbitrary genomic loci is protein-fragment complementation assay (PCA). In PCA two proteins of interest (targets) are genetically linked to two moieties of an enzyme (reporter) that can confer resistance to the bacterium. Because the reporter is fully assembled only when the two target proteins interact, the fraction of surviving bacteria after an antibiotic treatment provides quantitative information regarding the interaction energies between the two proteins. It is assumed that this assay may be naturally transposed to the problem of the contact between two genomic loci.  
 +
In order to end this problem, Lagomarsino ''et al.'' suggesting to target directly two genomic loci. For instance, the CRISPR/Cas9 system with two different short sgRNAs could be used to direct the target, a modified Cas9 with no endonuclease property, to the genomic loci. The modified Cas9 would then be used in two different fused systems, each one containing one reporter moiety. <b>[Fig. 1]</b>.  In our project we chose tripartite split-GFP as a marker.
 
[[File:Paris_Saclay--perspective.png|700px|center|]]
 
[[File:Paris_Saclay--perspective.png|700px|center|]]
  
A possible PCA-Cas9 assay to select bacteria on the basis of physical contacts between pairs of genomic loci. On the one hand, two short guide RNAs (sgRNA1 and sgRNA2) are used to recognize two specific genomic loci (in red and blue) distantly situated along the genome. On the other hand, the Cas9 protein, which is modified to have no endonuclease activity, is used in two different fused systems. Each fused system contains one moiety (X or Y) of a reporter protein (X–Y) that can confer either survival to the bacteria, as in a DHFR system '' (Remy et al. 2007)'' , or fluorescence, as in a FRET system '' (Miyawaki et al. 2011)'' . Both cases enable the selection of bacteria that have brought X and Y (i.e., the two genomic loci) into contact. See '' (Mali et al. 2013)''  for a more general discussion about the engineering potential of CRISPR-Cas9 systems.
+
A possible PCA-Cas9 assay to select bacteria on the basis of physical contacts between pairs of genomic loci. On the one hand, two short guide RNAs (sgRNA1 and sgRNA2) are used to recognize two specific genomic loci (in red and blue) distantly situated along the genome. On the other hand, the dCas9 protein is used in two different fused systems. Each fused system contains one moiety (X or Y) of a reporter protein (X–Y) that can confer either survival to the bacteria, as in a DHFR system '' (Remy et al. 2007)'' , or fluorescence, as in a FRET system '' (Miyawaki et al. 2011)'' . Both cases enable the selection of bacteria that have brought X and Y (i.e., the two genomic loci) into contact. See '' (Mali et al. 2013)''  for a more general discussion about the engineering potential of CRISPR-Cas9 systems.
  
=Enhance the expression of any genes: epigenetic engineering=
+
=changing the expression of any genes: epigenetic engineering=
 
+
The global goal of our project is to study the impact of the spatial organization of the chromosome on the genetic transcription. For that purpose, we designed a tool to characterize the effect of a strong promoter on a weak promoter in space. With our tool we are able to study how we can change the strength of one desired promotor according to DNA topology. This enhancement of the transcription of the gene controlled by the weak promoter could be very interesting in many fields and could be used for research and in the industry. Indeed, promoter strength, or activity, is important in genetic engineering and synthetic biology. Furthermore, this enhancement is based on the chromosome organization, the tool we designed correspond to an ‘’epigenetic’’ engineering tool.
+
  
 +
The global goal of our project is to study the impact of the spatial organization of the chromosome on the genetic transcription. For that purpose, we designed a tool to characterize the effect of a strong promoter on a weak promoter in space. With our tool we are able to study how we can change the strength of one desired promoter according to DNA topology. This enhancement of the transcription of the gene controlled by the weak promoter could be very interesting in many fields and could be used for research and in the industry. Indeed, promoter strength, or activity, is important in genetic engineering and synthetic biology. Furthermore, this enhancement is based on the chromosome organization, the tool we designed correspond to an ‘’epigenetic’’ engineering tool.
  
 
In order to increase the expression of a specific gene on the bacterial chromosome, a classic method is to choose one promoter with a suitable strength which can be employed to regulate the rate of transcription, which then leads to the required level of protein expression. For this purpose, so far, many promoter libraries have been established experimentally '' (Li & Zhang, 2014) ''. Then the strategy is to clone the chosen promoter just before the gene sequence <b>[Fig. 2a]</b>. With our tool, we offer a new strategy which also involves a cloning (the plasmid of interest) but no insertion in the bacterial chromosome, which is an advantage!
 
In order to increase the expression of a specific gene on the bacterial chromosome, a classic method is to choose one promoter with a suitable strength which can be employed to regulate the rate of transcription, which then leads to the required level of protein expression. For this purpose, so far, many promoter libraries have been established experimentally '' (Li & Zhang, 2014) ''. Then the strategy is to clone the chosen promoter just before the gene sequence <b>[Fig. 2a]</b>. With our tool, we offer a new strategy which also involves a cloning (the plasmid of interest) but no insertion in the bacterial chromosome, which is an advantage!
  
We believe that with our tool it is possible to increase or decrease the strength of a given promotor by changing the DNA topology. This method does not necessitate the insertion of new promotor on the bacterial genome. In this method it is enough to design two sgRNAs for 2 regions of DNA which are situated in the optimal distance to the target promotors. The online bioinformatics tools also are available to in order to design the sgRNA by bio-informatics '' (Kim & Kim, 2014) ''. When the plasmids coding for our tools (customized with designed sgRNAs) transformed to the bacteria, it is able to change the strength of a given promoter <b>[Fig. 2b]</b>.
+
We believe that with our tool it is possible to increase or decrease the strength of a given promoter by changing the DNA topology. This method does not necessitate the insertion of a new promoter in the bacterial genome. In this method it is enough to design two sgRNAs to target two DNA regions which are situated in the optimal distance from the promoters of interest. Online bioinformatics tools are also available in order to design the sgRNAs'' (Kim & Kim, 2014) ''. When the plasmids coding for our tools (customized with designed sgRNAs) is transformed into the bacteria, it is able to change the strength of a given promoter <b>[Fig. 2b]</b>.
  
 
[[File:Paris_Saclay--Perspective.png|700px|center|]]
 
[[File:Paris_Saclay--Perspective.png|700px|center|]]
 +
<center>'''Figure 2''' : Different ways to enhance gene expression</center>
 +
  
 
(A) Classic method: insert a plasmid to clone a strong promoter in front of the gene
 
(A) Classic method: insert a plasmid to clone a strong promoter in front of the gene
Line 29: Line 32:
  
 
(C) iJ’Aime method 2: insert iJ’AIME ribonucleoprotein
 
(C) iJ’Aime method 2: insert iJ’AIME ribonucleoprotein
 
===Compatibility of our system with the industry===
 
 
The compatibility issue of our system with the industry and the industrial scales seems to be the main issue. In the field of white biotechnologies (meaning industrial biotechnologies), it exists a lot of improved strains in order to produce economically speaking interesting compounds.  Two ways exist to produce an interesting compound by a biological way (most of time bacteria or yeast):
 
 
* Bioconversion: the conversion of one chemical compound, or one form of energy, into another by living organisms
 
* ‘’De novo’’ synthesis: synthesis of complex molecules from simple molecules such as sugars or amino acids
 
 
There are many advantages for a company to produce compounds by micro-organisms: it is generally cheaper (when the process is controlled) and eco-friendlier than compounds produced by chemical ways. Furthermore, the strains used are produced by genetic engineering and more and more by synthetic biology. A lot of the genetic engineering work consists of an improvement of the expression of some specific genes, which could be done also with out tool. The wide majority of these strains are GMOs as they own exogenous (meaning foreign) DNA on their genome. Once a company has the good strain (after many years and several million dollars), the strain is introduced in a big fermenter.
 
 
It exists now a lot of examples of such compounds produced by biological way but we focused ourselves on one specific example. In recent years, biotechnology-derived production of flavors and fragrances has expanded rapidly. The world's most popular flavor, vanillin, is no exception. Thus, it exists a wide range of biotechnology-based vanillin synthesis with the use of ferulic acid, eugenol, and glucose as substrates and bacteria, fungi, and yeasts as microbial production hosts (Gallage and Møller, 2015).
 
 
Our system seems to be a good solution for synthetic biology, but the expression of our tool via the plasmid previously inserted in bacteria is transient, meaning that the expression of our tool in the bacteria is limited in time. Furthermore, rapamicyn should be added in the fermenter in order to fuse our tool, which could be an issue concerning the composition of the fermenter. This point is crucial and constitutes the go/no-go step of the commercialization of our project.  A solution to this problem is described in the next part.
 
  
 
=Production of non-GMO strains for the industry =
 
=Production of non-GMO strains for the industry =
Line 48: Line 38:
  
  
However, our system still can be considered as a genetic modification in bacteria (expression plasmid containing foreign DNA). The recent works on the use of CRISPR/Cas9 system help us to overcome this issue as well. It is possible to introduce the dCas9 ribonucleoproteins (RNP), which consist of purified dCas9 protein in complex with a sgRNA instead of transformation of coding plasmids. They are assembled in vitro and can be delivered directly to cells using standard electroporation or transfection techniques '' (McDade, 2016) ''. So it can be possible to deliver directly our tool by this method <b>[Fig. 2c]</b>. As no foreign DNA is introduced, the organisms manipulated by our tool should not be considered as GMOs!
+
However, our system still can be considered as a genetic modification of bacteria (expression plasmid containing foreign DNA). But recent works on the use of CRISPR/Cas9 system help us to overcome this issue as well. It is possible to introduce the dCas9 ribonucleoproteins (RNP), which consists in a purified dCas9 protein in complex with a sgRNA, un the cell without doing a transformation of coding plasmids. They are assembled in vitro and can be delivered directly to cells, using standard electroporation or transfection techniques '' (McDade and Waxmonsky ,2016) ''.In conclusion, it is possible to deliver directly our tool by this method <b> [Fig. 2c] </b>. As no foreign DNA is introduced, the organisms manipulated by our tool should not be considered as GMOs!
  
 
=References=
 
=References=
  
http://www.college-de-france.fr/site/en-cirb/espeli.htm
+
Kim H, Kim J-S. A guide to genome engineering with programmable nucleases. '' Nature Reviews Genetics. '' 2 avr 2014;15(5):321‑34
 
+
Lagomarsino MC, Espéli O, Junier I. From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments. FEBS Letters. 7 oct 2015;589(20PartA):2996‑3004. http://dx.doi.org/10.1016/j.febslet.2015.07.002
+
 
+
P. Mali , K.M. Esvelt , G.M. Church , Cas9 as a versatile tool for engineering biology. Nat. Methods, 10, 10 (2013), 957– 963.
+
 
+
I. Remy , F.X. Campbell-Valois , S.W. Michnick , Detection of protein–protein interactions using a simple survival protein-fragment complementation assay based on the enzyme dihydrofolate reductase. Nat. Protoc., 2, 9 (2007), 2120– 2125.
+
 
+
A. Miyawaki , Development of probes for cellular functions using fluorescent proteins and fluorescence resonance energy transfer. Annu. Rev. Biochem., 80, (2011), 357– 373.
+
 
+
  
Li J, Zhang Y. Relationship between promoter sequence and its strength in gene expression. Eur Phys J E Soft Matter. sept 2014;37(9):44. http://link.springer.com/article/10.1140%2Fepje%2Fi2014-14086-1
+
Lagomarsino, M., Espéli, O. and Junier, I. 2015. From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments. '' FEBS letters. '' 589, 20 Pt A (2015), 2996–3004.
  
Kim H, Kim J-S. A guide to genome engineering with programmable nucleases. Nature Reviews Genetics. 2 avr 2014;15(5):321‑34. https://www.ncbi.nlm.nih.gov/pubmed/24690881
+
Li, J. and Zhang, Y. 2014. Relationship between promoter sequence and its strength in gene expression. '' arXiv. '' (2014).
 +
Mali, P., Esvelt, K. and Church, G. 2013. Cas9 as a versatile tool for engineering biology. '' Nature Methods. '' 10, 10 (2013), 957–963.
  
Smith-Willis H, San Martin B. Revolutionizing genome editing with CRISPR/Cas9: patent battles and human embryos. Cell Gene Therapy Insights. 2015;1(2):253‑62. http://insights.bio/cell-and-gene-therapy-insights/?bio_journals=revolutionizing-genome-editing-with-crisprcas9-patent-battles-and-human-embryos
+
McDade JR, Waxmonsky NC (2016) Emerging CRISPR Technologies Available Through Resource Sharing. '' JSM Genet Genomics''  3(1): 1008.
  
http://www.clontech.com/US/Products/Inducible_Systems/Protein-Protein_Interactions/iDimerize_Product_Overview
+
Miyawaki, A. 2011. Development of Probes for Cellular Functions Using Fluorescent Proteins and Fluorescence Resonance Energy Transfer. '' Annual Review of Biochemistry. ''  80, 1 (2011), 357–373.  
  
Gallage NJ, Møller BL. Vanillin–Bioconversion and Bioengineering of the Most Popular Plant Flavor and Its De Novo Biosynthesis in the Vanilla Orchid. Molecular Plant. janv 2015;8(1):40‑57. https://www.ncbi.nlm.nih.gov/pubmed/25578271
+
Remy, I., Campbell-Valois, F. and Michnick, S. 2007. Detection of protein-protein interactions using a simple survival protein-fragment complementation assay based on the enzyme dihydrofolate reductase. '' Nature protocols. '' 2, 9 (2007), 2120–5.
  
http://blog.addgene.org/genome-engineering-using-cas9/grna-ribonucleoproteins-rnps
 
  
  
 
{{Team:Paris_Saclay/project_footer}}
 
{{Team:Paris_Saclay/project_footer}}

Latest revision as of 12:45, 19 October 2016

Perspective

Perspective

In this project we design a tool to study the relation between DNA structure and gene expression. Here we propose many applications of our tool in genome study and industry. Using dCas9 in this system would give us the advantage to specifically target the desired sequence and change the structure of the DNA. Indeed, it would be possible to design specific sgRNA to target specific sequences.

Study the chromosome structure and function

Our tool can be considered as a reporter for chromosome structural properties. According to Lagomarsino et al., developing a stable reporter is the most important challenge in chromosome structural studies. (Lagomarsino et al., 2015). One of the classic technics to study the contact between two arbitrary genomic loci is protein-fragment complementation assay (PCA). In PCA two proteins of interest (targets) are genetically linked to two moieties of an enzyme (reporter) that can confer resistance to the bacterium. Because the reporter is fully assembled only when the two target proteins interact, the fraction of surviving bacteria after an antibiotic treatment provides quantitative information regarding the interaction energies between the two proteins. It is assumed that this assay may be naturally transposed to the problem of the contact between two genomic loci. In order to end this problem, Lagomarsino et al. suggesting to target directly two genomic loci. For instance, the CRISPR/Cas9 system with two different short sgRNAs could be used to direct the target, a modified Cas9 with no endonuclease property, to the genomic loci. The modified Cas9 would then be used in two different fused systems, each one containing one reporter moiety. [Fig. 1]. In our project we chose tripartite split-GFP as a marker.

Paris Saclay--perspective.png

A possible PCA-Cas9 assay to select bacteria on the basis of physical contacts between pairs of genomic loci. On the one hand, two short guide RNAs (sgRNA1 and sgRNA2) are used to recognize two specific genomic loci (in red and blue) distantly situated along the genome. On the other hand, the dCas9 protein is used in two different fused systems. Each fused system contains one moiety (X or Y) of a reporter protein (X–Y) that can confer either survival to the bacteria, as in a DHFR system (Remy et al. 2007) , or fluorescence, as in a FRET system (Miyawaki et al. 2011) . Both cases enable the selection of bacteria that have brought X and Y (i.e., the two genomic loci) into contact. See (Mali et al. 2013) for a more general discussion about the engineering potential of CRISPR-Cas9 systems.

changing the expression of any genes: epigenetic engineering

The global goal of our project is to study the impact of the spatial organization of the chromosome on the genetic transcription. For that purpose, we designed a tool to characterize the effect of a strong promoter on a weak promoter in space. With our tool we are able to study how we can change the strength of one desired promoter according to DNA topology. This enhancement of the transcription of the gene controlled by the weak promoter could be very interesting in many fields and could be used for research and in the industry. Indeed, promoter strength, or activity, is important in genetic engineering and synthetic biology. Furthermore, this enhancement is based on the chromosome organization, the tool we designed correspond to an ‘’epigenetic’’ engineering tool.

In order to increase the expression of a specific gene on the bacterial chromosome, a classic method is to choose one promoter with a suitable strength which can be employed to regulate the rate of transcription, which then leads to the required level of protein expression. For this purpose, so far, many promoter libraries have been established experimentally (Li & Zhang, 2014) . Then the strategy is to clone the chosen promoter just before the gene sequence [Fig. 2a]. With our tool, we offer a new strategy which also involves a cloning (the plasmid of interest) but no insertion in the bacterial chromosome, which is an advantage!

We believe that with our tool it is possible to increase or decrease the strength of a given promoter by changing the DNA topology. This method does not necessitate the insertion of a new promoter in the bacterial genome. In this method it is enough to design two sgRNAs to target two DNA regions which are situated in the optimal distance from the promoters of interest. Online bioinformatics tools are also available in order to design the sgRNAs (Kim & Kim, 2014) . When the plasmids coding for our tools (customized with designed sgRNAs) is transformed into the bacteria, it is able to change the strength of a given promoter [Fig. 2b].

Paris Saclay--Perspective.png
Figure 2 : Different ways to enhance gene expression


(A) Classic method: insert a plasmid to clone a strong promoter in front of the gene

(B) iJ’Aime method 1: insert a plasmid to express iJ’AIME tool

(C) iJ’Aime method 2: insert iJ’AIME ribonucleoprotein

Production of non-GMO strains for the industry

As it was mentioned before, the wide majority of the strains used in the bio-industry are GMOs. To learn more about GMO regulation, click here. There is a debate in the European Union in order to decide if organisms modified by CRISPR/Cas9 technology should be considered as GMO or not. Nevertheless, this debate is only for CRISPR/Cas9 doing a double strand break (DSB) in the chromosome. In our tool we use dCas9 proteins, the Cas9 protein in which the exonuclease (cutting) activity is enabled.


However, our system still can be considered as a genetic modification of bacteria (expression plasmid containing foreign DNA). But recent works on the use of CRISPR/Cas9 system help us to overcome this issue as well. It is possible to introduce the dCas9 ribonucleoproteins (RNP), which consists in a purified dCas9 protein in complex with a sgRNA, un the cell without doing a transformation of coding plasmids. They are assembled in vitro and can be delivered directly to cells, using standard electroporation or transfection techniques (McDade and Waxmonsky ,2016) .In conclusion, it is possible to deliver directly our tool by this method [Fig. 2c] . As no foreign DNA is introduced, the organisms manipulated by our tool should not be considered as GMOs!

References

Kim H, Kim J-S. A guide to genome engineering with programmable nucleases. Nature Reviews Genetics. 2 avr 2014;15(5):321‑34

Lagomarsino, M., Espéli, O. and Junier, I. 2015. From structure to function of bacterial chromosomes: Evolutionary perspectives and ideas for new experiments. FEBS letters. 589, 20 Pt A (2015), 2996–3004.

Li, J. and Zhang, Y. 2014. Relationship between promoter sequence and its strength in gene expression. arXiv. (2014). Mali, P., Esvelt, K. and Church, G. 2013. Cas9 as a versatile tool for engineering biology. Nature Methods. 10, 10 (2013), 957–963.

McDade JR, Waxmonsky NC (2016) Emerging CRISPR Technologies Available Through Resource Sharing. JSM Genet Genomics 3(1): 1008.

Miyawaki, A. 2011. Development of Probes for Cellular Functions Using Fluorescent Proteins and Fluorescence Resonance Energy Transfer. Annual Review of Biochemistry. 80, 1 (2011), 357–373.

Remy, I., Campbell-Valois, F. and Michnick, S. 2007. Detection of protein-protein interactions using a simple survival protein-fragment complementation assay based on the enzyme dihydrofolate reductase. Nature protocols. 2, 9 (2007), 2120–5.