Template:Team:Tokyo-NoKoGen/contents header
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+ | <h3 id="s1">"E. communication": E. coli that is capable of communication.</h1> | ||
+ | |||
+ | <h4>Abstract</h4> | ||
+ | TTThis year, we’d like to let E. coli communicate with each other like human beings using the concept of “optogenetics”. As the means of communication, we chose the “light”. An E. coli will emit light to pass on the light signal, the “message”, to the neighboring E. coli in a separate flask. When the neighbor receives the “message”, itself will emit light to pass on to the next E. coli. E. coli will relay the light signal, until all E. coli has received the “message”.<br> | ||
+ | <div class="imbox"><a href="../img/imageNKJ.JPG" target="new"><img src="../img/imageNKJ.JPG"></img></a><p>imageNKJ.JPG</p></div> | ||
+ | |||
+ | TTLight inducible gene expression system doesn't require any chemical inducer, so, there will be no need to remove chemical compounds from the medium, and can send the signal to E. coli located in independent vessels. This means that E. coli will be able to communicate swiftly and wirelessly by using light.<br> | ||
+ | <br> | ||
+ | |||
+ | To make communication faster, we are focusing on post transcriptional regulation. Regulating gene translation will make the network faster than regulating gene transcription.<br> | ||
+ | <div class="imbox"><a href="../img/Photobacterium.jpg" target="new"><img src="../img/Photobacterium.jpg"></a></img><p>Photobacterium.jpg</p></div> | ||
+ | <br> | ||
+ | <br> | ||
+ | <br> | ||
+ | <h4>Details</h4><br> | ||
+ | Transmitter (lux bioluminescence)<br> | ||
+ | <br> | ||
+ | TTWe use lux operon from luminous bacteria as the light source because we expect it to have a potential for emitting bright bioluminescence in E. coli.<br> | ||
+ | <br> | ||
+ | TTMoreover, we don't have to add any chemical compounds such as substrate, because, E. coli have all compounds needed to produce luminescence. | ||
+ | Receiver (rhodopsin)<br> | ||
+ | |||
+ | <br> | ||
+ | <br> | ||
+ | <br> | ||
+ | |||
+ | <h3 id="s2">"E. communication": E. coli that is capable of communication.</h1> | ||
+ | |||
+ | <h4>Abstract</h4> | ||
+ | <br> | ||
+ | TTThis year, we’d like to let E. coli communicate with each other like human beings using the concept of “optogenetics”. As the means of communication, we chose the “light”. An E. coli will emit light to pass on the light signal, the “message”, to the neighboring E. coli in a separate flask. When the neighbor receives the “message”, itself will emit light to pass on to the next E. coli. E. coli will relay the light signal, until all E. coli has received the “message”.<br> | ||
+ | <br> | ||
+ | TTLight inducible gene expression system doesn't require any chemical inducer, so, there will be no need to remove chemical compounds from the medium, and can send the signal to E. coli located in independent vessels. This means that E. coli will be able to communicate swiftly and wirelessly by using light.<br> | ||
+ | <br> | ||
+ | To make communication faster, we are focusing on post transcriptional regulation. Regulating gene translation will make the network faster than regulating gene transcription.<br> | ||
+ | <br> | ||
+ | <br> | ||
+ | <br> | ||
+ | <h4>Details</h4><br> | ||
+ | Transmitter (lux bioluminescence)<br> | ||
+ | <br> | ||
+ | TTWe use lux operon from luminous bacteria as the light source because we expect it to have a potential for emitting bright bioluminescence in E. coli.<br> | ||
+ | <br> | ||
+ | TTMoreover, we don't have to add any chemical compounds such as substrate, because, E. coli have all compounds needed to produce luminescence. | ||
+ | Receiver (rhodopsin)<br> | ||
+ | |||
+ | |||
+ | <p id="period"></p> | ||
+ | </div> | ||
+ | </div> | ||
+ | </div> | ||
</div> | </div> | ||
</html> | </html> |
Revision as of 13:52, 12 September 2012
"E. communication": E. coli that is capable of communication.
Abstract
TTThis year, we’d like to let E. coli communicate with each other like human beings using the concept of “optogenetics”. As the means of communication, we chose the “light”. An E. coli will emit light to pass on the light signal, the “message”, to the neighboring E. coli in a separate flask. When the neighbor receives the “message”, itself will emit light to pass on to the next E. coli. E. coli will relay the light signal, until all E. coli has received the “message”.
TTLight inducible gene expression system doesn't require any chemical inducer, so, there will be no need to remove chemical compounds from the medium, and can send the signal to E. coli located in independent vessels. This means that E. coli will be able to communicate swiftly and wirelessly by using light.
To make communication faster, we are focusing on post transcriptional regulation. Regulating gene translation will make the network faster than regulating gene transcription.
Details
Transmitter (lux bioluminescence)
TTWe use lux operon from luminous bacteria as the light source because we expect it to have a potential for emitting bright bioluminescence in E. coli.
TTMoreover, we don't have to add any chemical compounds such as substrate, because, E. coli have all compounds needed to produce luminescence.
Receiver (rhodopsin)
"E. communication": E. coli that is capable of communication.
Abstract
TTThis year, we’d like to let E. coli communicate with each other like human beings using the concept of “optogenetics”. As the means of communication, we chose the “light”. An E. coli will emit light to pass on the light signal, the “message”, to the neighboring E. coli in a separate flask. When the neighbor receives the “message”, itself will emit light to pass on to the next E. coli. E. coli will relay the light signal, until all E. coli has received the “message”.
TTLight inducible gene expression system doesn't require any chemical inducer, so, there will be no need to remove chemical compounds from the medium, and can send the signal to E. coli located in independent vessels. This means that E. coli will be able to communicate swiftly and wirelessly by using light.
To make communication faster, we are focusing on post transcriptional regulation. Regulating gene translation will make the network faster than regulating gene transcription.
Details
Transmitter (lux bioluminescence)
TTWe use lux operon from luminous bacteria as the light source because we expect it to have a potential for emitting bright bioluminescence in E. coli.
TTMoreover, we don't have to add any chemical compounds such as substrate, because, E. coli have all compounds needed to produce luminescence.
Receiver (rhodopsin)
Abstract
TTThis year, we’d like to let E. coli communicate with each other like human beings using the concept of “optogenetics”. As the means of communication, we chose the “light”. An E. coli will emit light to pass on the light signal, the “message”, to the neighboring E. coli in a separate flask. When the neighbor receives the “message”, itself will emit light to pass on to the next E. coli. E. coli will relay the light signal, until all E. coli has received the “message”.
TTLight inducible gene expression system doesn't require any chemical inducer, so, there will be no need to remove chemical compounds from the medium, and can send the signal to E. coli located in independent vessels. This means that E. coli will be able to communicate swiftly and wirelessly by using light.
To make communication faster, we are focusing on post transcriptional regulation. Regulating gene translation will make the network faster than regulating gene transcription.
Details
Transmitter (lux bioluminescence)
TTWe use lux operon from luminous bacteria as the light source because we expect it to have a potential for emitting bright bioluminescence in E. coli.
TTMoreover, we don't have to add any chemical compounds such as substrate, because, E. coli have all compounds needed to produce luminescence. Receiver (rhodopsin)