Glasgow/Wetlab/Goals
From 2007.igem.org
DavidGilbert (Talk | contribs) |
|||
(7 intermediate revisions not shown) | |||
Line 1: | Line 1: | ||
{| valign=top cellpadding=3 | {| valign=top cellpadding=3 | ||
|- | |- | ||
- | !align=center|[ | + | !align=center|[[Image:Uog.jpg]] || || [[Glasgow|<font face=georgia color=#3366CC size=4>Back To <br> Glasgow's <br> Main Page</font>]] || [[Glasgow/Plan|<font face=georgia color=#3366CC size=4>Back To <br> Glasgow's <br> Project Page</font>]] |
|} | |} | ||
---- | ---- | ||
+ | <font face=georgia color=#3366CC size=4>'''Main Goals of Glasgow Project'''</font> | ||
+ | #Design and make new BioBricks for detection systems: XylR, Pu, Pr, DntR and DntA. | ||
+ | #Design and make new BioBricks for the production of pyocyanin. | ||
+ | #Clone genes and test responsiveness/sensitivity in non-pathogenic bacteria using ONPG. | ||
+ | #Clone genes into shuttle vector and test motility/transferability in both ''E. coli'' and pseudomonads. | ||
+ | #Get ''E. coli'' to produce pyocyanin. | ||
+ | #Improve efficiency of fuel cells. | ||
+ | #Make fuel cells with ''E. coli'' or pseudomonads which respond to stimuli to produce pyocyanin. | ||
+ | #Active collaboration between the biologists and the modellers to produce models that can accurately describe the behaviour of the chosen systems. | ||
+ | #Explore a variety of different computational approaches to study the behaviour of the chosen systems. | ||
+ | #Computational validation of hypotheses proposed by the biologists. |
Latest revision as of 13:59, 26 October 2007
Back To Glasgow's Main Page | Back To Glasgow's Project Page |
---|
Main Goals of Glasgow Project
- Design and make new BioBricks for detection systems: XylR, Pu, Pr, DntR and DntA.
- Design and make new BioBricks for the production of pyocyanin.
- Clone genes and test responsiveness/sensitivity in non-pathogenic bacteria using ONPG.
- Clone genes into shuttle vector and test motility/transferability in both E. coli and pseudomonads.
- Get E. coli to produce pyocyanin.
- Improve efficiency of fuel cells.
- Make fuel cells with E. coli or pseudomonads which respond to stimuli to produce pyocyanin.
- Active collaboration between the biologists and the modellers to produce models that can accurately describe the behaviour of the chosen systems.
- Explore a variety of different computational approaches to study the behaviour of the chosen systems.
- Computational validation of hypotheses proposed by the biologists.