Team:EPF Lausanne/Project asaia

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One of the main goals of our project is to establish Asaia as a new chassis. Hence, we will make a lot of characterization experiment, so that other teams will be able to quickly and efficiently engineer new and more potent Asaia strains.
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=Asaia: A new chassis to fight mosquito-borne diseases=
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Among the bacteria that naturally live in the mosquito's intestinal tract, we chose the bacteria Asaia because of its high rate of transmission between mosquitoes. Indeed, it seems that Asaia is transmitted horizontally (from one mosquito to another) but also vertically (from parent to offspring). These properties of Asaia make it a really good candidate for our project. Indeed, a lot of mosquitoes would have to be infected with our engineered Asaia before any significant reductions of malaria transmission could occur.  
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[[Image:ID card.png|right|300px|caption]]
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Asaia is a pink bacterium collected from tropical flowers in Thailand and Indonesia [ [[#References:|1]] ]. It has been proven to naturally live in the mosquito's intestinal tract and to have a high rate of transmission between mosquitos, both horizontally (from one mosquito to another) and vertically (from parent to offspring)[ [[#References:|2]] ]. The vertical and horizontal transmission as well as the cross-colonizing capacity of Asaia (as reported in literature [ [[#References:|3]] ]) could assure the spread of the transformed agent through a host population. It also appears to be quite specific to mosquitoes, and would therefore have little risk of spreading to other insects. However, there is experimental evidence that Asaia is  able to cross-colonize different species of mosquitoes and does not exert any pathogenic effect on the host[ [[#References:|4]] ]. Therefore, Asaia is considered to be useful to the  mosquito, because of its 100% prevalence as well as its preservation in  laboratory conditions [ [[#References:|5]] ].  
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We believe it could be a really good instrument in the fight against malaria and other mosquito-borne diseases.
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[[Image:Doctor.png|left|150px|caption‎]]
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[[Image:ID card.png|center|500px|caption]]
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These properties make it a very good candidate for our project, which consists in blocking the infection cycle of [https://2010.igem.org/wiki/index.php?title=Team:EPF_Lausanne/Project_malaria Malaria]. To assess if Asaia is actually a good organism to work on, our team at EPFL decided to study and characterize it: we worked on the strain SF2.1(Gfp) [ [[#References:|2]] ]which turned out is relatively easy to manipulate. Our team provides iGEM with a new chassis, and the necessary protocols for future teams that want to keep working on this promising organism.
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In this page we want to summarize the main properties coming out from our experiments.
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We believe "Asaia" could be a good instrument in the fight against malaria and other mosquito-borne diseases.
 +
 
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In this page we summarize the main results related to growing and working with "Asaia".
 +
 
 +
== Do you want to work with Asaia?==
 +
No problem! You can find in the following tech-sheets all the information, protocols and tricks you need to start your own project.
 +
 
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*[https://static.igem.org/mediawiki/2010/3/3b/Growing_Asaia.pdf Growing Asaia]
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*[https://static.igem.org/mediawiki/2010/c/c5/Competent_cells.pdf Competent cells]
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*[https://static.igem.org/mediawiki/2010/a/a6/Transformation.pdf Transformation]
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*[https://static.igem.org/mediawiki/2010/9/95/Cloning_into_Asaia.pdf Cloning into Asaia]
= Doubling Time =
= Doubling Time =
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We measured the growth curve of Asaia at differents pH (ph2-pH7) and at 30°C and 37°C to figure out the optimal growth conditions.
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[[Image:microscope.png|left|100px|caption]]
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We measured the growth curve of Asaia at different pH (pH2-pH7) and at 30°C and 37°C to figure out the optimal growth conditions.
We found that the optimal Temperature is 30°C, and the optimal pH is 5.
We found that the optimal Temperature is 30°C, and the optimal pH is 5.
At this conditions we measured a <b>doubling time of 2h40min</b>.
At this conditions we measured a <b>doubling time of 2h40min</b>.
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[[Image:Graph growth curve2.jpg]]
 
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= Antibiotic resistance =
 
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We are actually characterizing Asaia's properties against various antibiotics.
 
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We've already noticed that Asaia is naturally resistant to Amphicillin (Amp) and Chloroamphenicol (Cm) to the standard concentrations for E.Coli.
 
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We are testing right now the behaviour of Asaia to 7 others antibiotic like Tetracyclin (Tet) and Kanamycin (Kan) at various concentrations.
 
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[[Image:Graph growth curve2.jpg|center]]
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= Compatibility with E.Coli =
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= Antibiotic resistance =
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We characterized Asaia's resistance against various antibiotics.
 +
We had noticed previously that Asaia is naturally resistant to Ampicillin (Amp) and Chloroamphenicol (Cm) using the standard concentrations generally used with ''E. coli''.
 +
We tested the behaviour of Asaia to 7 other antibiotics like Tetracyclin (Tet) and Kanamycin (Kan) at various concentrations.
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We noticed that the Origin of replication of Asaia is compatible with E.Coli, but the opposite is not true. The origin of replication of E.Coli isn't compatible with Asaia.
 
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Thus, we had to add Asaia's origin of replication to all our parts so they would function in both Asaia and E.Coli
 
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[[Image:Graph Resistance2.jpg|thumb|center|500px|Here you can see the doubling time as a function of antibiotic concentration. When Asaia didn't grow, the doubling time is arbitrarily set to 10h]]
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[[Image:EPFL_ResArray.jpg|thumb|center|500px||Here is our plate with different concentrations of antibiotics. Green holes are filled with growing Asaia.]]
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=Microscope Images of Asaia=
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We also had a look at Asaia (containing a plasmid expressing GFP) with the microscope. It looks very similar to <i>E.coli</i>.
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[[Image:EPFL-Asaia-microscopy.jpg|thumb|center|500px||Brightfield (top) and a GFP fluorescence (bottom) picture of the Asaia strain containing the Plasmid pHM2-GFP]]
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= Compatibility with ''E. coli'' =
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[[Image:Copain.png|right|250px|caption]]
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We noticed that ''Asaia's'' origin of replication is compatible with ''E. coli'', but the opposite is not true.
 +
Therefore, we had to add ''Asaia's'' origin of replication to all our parts so they would function in both ''Asaia'' and ''E. coli''
 +
==References==
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*[http://ijs.sgmjournals.org/cgi/reprint/51/2/559.pdf 1. Kazushige Katsura, ''Asaia siamensis sp. nov., an acetic acid bacterium in the α-Proteobacteria'',International Journal of Systematic and Evolutionary Microbiology (2001)]
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*[http://www.pnas.org/content/104/21/9047.long#sec-7. 2. Guido Favia, ''Bacteria of the genus Asaia stably associate with Anopheles stephensi, an Asian malarial mosquito vector '']
 +
*[http://aem.asm.org/cgi/content/abstract/AEM.01336-10v1. 3. Crotti et al, ''Acetic acid bacteria, new emerging symbionts of insects'' (2010)]
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*[http://aem.asm.org/cgi/reprint/AEM.01747-10v1?view=long&pmid=20851960. 4. Bessem et al, ''Typing of Asaia spp. bacterial symbionts in four mosquito species: molecular evidence for multiple infections'' (2010)]
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*[http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1885625/ 5. Guido et al,''Bacteria of the genus Asaia stably associate with Anopheles stephensi, an Asian malarial mosquito vector'' (2007)]
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Latest revision as of 20:13, 27 October 2010



Contents

Asaia: A new chassis to fight mosquito-borne diseases

caption

Asaia is a pink bacterium collected from tropical flowers in Thailand and Indonesia [ 1 ]. It has been proven to naturally live in the mosquito's intestinal tract and to have a high rate of transmission between mosquitos, both horizontally (from one mosquito to another) and vertically (from parent to offspring)[ 2 ]. The vertical and horizontal transmission as well as the cross-colonizing capacity of Asaia (as reported in literature [ 3 ]) could assure the spread of the transformed agent through a host population. It also appears to be quite specific to mosquitoes, and would therefore have little risk of spreading to other insects. However, there is experimental evidence that Asaia is able to cross-colonize different species of mosquitoes and does not exert any pathogenic effect on the host[ 4 ]. Therefore, Asaia is considered to be useful to the mosquito, because of its 100% prevalence as well as its preservation in laboratory conditions [ 5 ].

caption‎

These properties make it a very good candidate for our project, which consists in blocking the infection cycle of Malaria. To assess if Asaia is actually a good organism to work on, our team at EPFL decided to study and characterize it: we worked on the strain SF2.1(Gfp) [ 2 ]which turned out is relatively easy to manipulate. Our team provides iGEM with a new chassis, and the necessary protocols for future teams that want to keep working on this promising organism.

We believe "Asaia" could be a good instrument in the fight against malaria and other mosquito-borne diseases.

In this page we summarize the main results related to growing and working with "Asaia".

Do you want to work with Asaia?

No problem! You can find in the following tech-sheets all the information, protocols and tricks you need to start your own project.

Doubling Time

caption

We measured the growth curve of Asaia at different pH (pH2-pH7) and at 30°C and 37°C to figure out the optimal growth conditions. We found that the optimal Temperature is 30°C, and the optimal pH is 5. At this conditions we measured a doubling time of 2h40min.


Graph growth curve2.jpg

Antibiotic resistance

We characterized Asaia's resistance against various antibiotics. We had noticed previously that Asaia is naturally resistant to Ampicillin (Amp) and Chloroamphenicol (Cm) using the standard concentrations generally used with E. coli. We tested the behaviour of Asaia to 7 other antibiotics like Tetracyclin (Tet) and Kanamycin (Kan) at various concentrations.



Here you can see the doubling time as a function of antibiotic concentration. When Asaia didn't grow, the doubling time is arbitrarily set to 10h
Here is our plate with different concentrations of antibiotics. Green holes are filled with growing Asaia.

Microscope Images of Asaia

We also had a look at Asaia (containing a plasmid expressing GFP) with the microscope. It looks very similar to E.coli.

Brightfield (top) and a GFP fluorescence (bottom) picture of the Asaia strain containing the Plasmid pHM2-GFP

Compatibility with E. coli

caption

We noticed that Asaia's origin of replication is compatible with E. coli, but the opposite is not true. Therefore, we had to add Asaia's origin of replication to all our parts so they would function in both Asaia and E. coli


References

  • [http://ijs.sgmjournals.org/cgi/reprint/51/2/559.pdf 1. Kazushige Katsura, Asaia siamensis sp. nov., an acetic acid bacterium in the α-Proteobacteria,International Journal of Systematic and Evolutionary Microbiology (2001)]
  • [http://www.pnas.org/content/104/21/9047.long#sec-7. 2. Guido Favia, Bacteria of the genus Asaia stably associate with Anopheles stephensi, an Asian malarial mosquito vector ]
  • [http://aem.asm.org/cgi/content/abstract/AEM.01336-10v1. 3. Crotti et al, Acetic acid bacteria, new emerging symbionts of insects (2010)]
  • [http://aem.asm.org/cgi/reprint/AEM.01747-10v1?view=long&pmid=20851960. 4. Bessem et al, Typing of Asaia spp. bacterial symbionts in four mosquito species: molecular evidence for multiple infections (2010)]
  • [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1885625/ 5. Guido et al,Bacteria of the genus Asaia stably associate with Anopheles stephensi, an Asian malarial mosquito vector (2007)]

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