Team:SDU-Denmark
From 2009.igem.org
(→Announcements) |
(→Our project in 1 minute) |
||
(5 intermediate revisions not shown) | |||
Line 19: | Line 19: | ||
[[Image:SDU-Denmark-skematic1.jpg|200px|right|Text]] | [[Image:SDU-Denmark-skematic1.jpg|200px|right|Text]] | ||
- | Our goal was to create an ''E. coli'' strain, which inhibits ''S. aureus'' biofilm formation in wounds by producing RNA III-inhibiting-peptide (RIP). | + | Our goal was to create an ''E. coli'' strain, which inhibits ''S. aureus'' biofilm formation in wounds by producing RNA III-inhibiting-peptide (''RIP''). |
''S. aureus'' is one of the largest causes of hospital infections, each year infecting millions of people around the globe. ''S. aureus'' is normally commensal, but can create bacterial biofilms on implanted medical devices and in post-operational wounds. Biofilm is becoming increasingly hard to treat, as a result of growing resistance to many types of antibiotics. | ''S. aureus'' is one of the largest causes of hospital infections, each year infecting millions of people around the globe. ''S. aureus'' is normally commensal, but can create bacterial biofilms on implanted medical devices and in post-operational wounds. Biofilm is becoming increasingly hard to treat, as a result of growing resistance to many types of antibiotics. | ||
- | By manipulating ''E. coli'' to express the synthetic RIP peptide, we have reached this goal. RIP has been shown to hinder the quorum-sensing processes essential for biofilm development in ''S. aureus'', making it harder for the bacteria to spread, and at the same time, improving the chance that conventional antibiotics will work. | + | By manipulating ''E. coli'' to express the synthetic RIP peptide, we have reached this goal. ''RIP'' has been shown to hinder the quorum-sensing processes essential for biofilm development in ''S. aureus'', making it harder for the bacteria to spread, and at the same time, improving the chance that conventional antibiotics will work. |
- | We propose making a bandage that contains our engineered bacteria behind a semipermeable membrane, allowing only small peptides such as RIP to pass through, into the wound. We hope to show that biological machines can be used to fight different kinds of bacterial infections intelligently, to contribute with our RIP and export-signal parts and by better characterization of the older parts we've used. | + | We propose making a bandage that contains our engineered bacteria behind a semipermeable membrane, allowing only small peptides such as ''RIP'' to pass through, into the wound. We hope to show that biological machines can be used to fight different kinds of bacterial infections intelligently, to contribute with our ''RIP'' and export-signal parts and by better characterization of the older parts we've used. |
[https://2009.igem.org/Team:SDU-Denmark/Project Our Project] | [https://2009.igem.org/Team:SDU-Denmark/Background Background for the project] | [https://2009.igem.org/Team:SDU-Denmark/Project Our Project] | [https://2009.igem.org/Team:SDU-Denmark/Background Background for the project] | ||
Line 33: | Line 33: | ||
<div id="h1-sdu"> | <div id="h1-sdu"> | ||
+ | |||
=University of Southern Denmark= | =University of Southern Denmark= | ||
</div> | </div> | ||
Line 42: | Line 43: | ||
We are from diverse backgrounds such as nano-bio-science, molecular biology and medicine. | We are from diverse backgrounds such as nano-bio-science, molecular biology and medicine. | ||
- | Together with six advisors, we | + | Together with six advisors, we've spend the summer getting to grips with the up’s and down’s in synthetic biology, the lab, how to organize the project and everything in between. |
[https://2009.igem.org/Team:SDU-Denmark/Team Our Team] | [http://igem.sdu.dk See what we're up to on our blog] | [https://2009.igem.org/Team:SDU-Denmark/Team Our Team] | [http://igem.sdu.dk See what we're up to on our blog] | ||
Line 51: | Line 52: | ||
<div class="teaser">What do you think?</div> | <div class="teaser">What do you think?</div> | ||
<div id="h1-feedback"> | <div id="h1-feedback"> | ||
+ | |||
=Feedback= | =Feedback= | ||
</div> | </div> | ||
Line 63: | Line 65: | ||
<div id="rightcontent"> | <div id="rightcontent"> | ||
- | + | ==Our project in 1 minute== | |
+ | |||
+ | [[Image:SDU-Denmark-Clock-Icon.gif|20px|right]] | ||
+ | |||
+ | We want to fight hospital infections, using a biological machine. | ||
+ | |||
+ | For this purpose we have constructed a recombinant ''E. coli'', which produces the ''RIP'' peptide. ''RIP'' inhibits biofilm formation in the bacteria ''S. aureus''. | ||
+ | |||
+ | This peptide will make it easier to fight infections and kill ''S. aureus'' with conventional antibiotics. | ||
+ | |||
==Announcements== | ==Announcements== | ||
- | |||
'''Oct. 21:''' Last minute panic updates are on the way :-) Expect some turbulence on the page for now. | '''Oct. 21:''' Last minute panic updates are on the way :-) Expect some turbulence on the page for now. |
Latest revision as of 23:35, 21 October 2009
Bacto-Bandage
Our goal was to create an E. coli strain, which inhibits S. aureus biofilm formation in wounds by producing RNA III-inhibiting-peptide (RIP).
S. aureus is one of the largest causes of hospital infections, each year infecting millions of people around the globe. S. aureus is normally commensal, but can create bacterial biofilms on implanted medical devices and in post-operational wounds. Biofilm is becoming increasingly hard to treat, as a result of growing resistance to many types of antibiotics.
By manipulating E. coli to express the synthetic RIP peptide, we have reached this goal. RIP has been shown to hinder the quorum-sensing processes essential for biofilm development in S. aureus, making it harder for the bacteria to spread, and at the same time, improving the chance that conventional antibiotics will work.
We propose making a bandage that contains our engineered bacteria behind a semipermeable membrane, allowing only small peptides such as RIP to pass through, into the wound. We hope to show that biological machines can be used to fight different kinds of bacterial infections intelligently, to contribute with our RIP and export-signal parts and by better characterization of the older parts we've used.
Our Project | Background for the project
University of Southern Denmark
We are eight students from the [http://www.sdu.dk University of Southern Denmark], who shared a common wish to explore synthetic biology and decided to start the first iGEM team at our university.
We are from diverse backgrounds such as nano-bio-science, molecular biology and medicine.
Together with six advisors, we've spend the summer getting to grips with the up’s and down’s in synthetic biology, the lab, how to organize the project and everything in between.
Our Team | [http://igem.sdu.dk See what we're up to on our blog]
Feedback
We would love to get as much feedback as possible, both on our project and other work as well. Feel free to write, criticize or just say hallo.
Our project in 1 minute
We want to fight hospital infections, using a biological machine.
For this purpose we have constructed a recombinant E. coli, which produces the RIP peptide. RIP inhibits biofilm formation in the bacteria S. aureus.
This peptide will make it easier to fight infections and kill S. aureus with conventional antibiotics.
Announcements
Oct. 21: Last minute panic updates are on the way :-) Expect some turbulence on the page for now.
Oct. 20: Brainstorm and team page updated.
Oct. 19: We made a [http://igem.sdu.dk/?p=354 sacrifice] to the Gods. Hopefully this will gives us the last bit of luck for the competition.
Oct. 18: We've been working hard on characterizing our parts and now we're getting ready for the final wiki upgrade
Oct. 16: We now have a couple on the team - Helle and Mike <3 congratulations! (Anne and Marc have actually been a couple for 4 years Anna)
Oct. 10: Colony-PCR protocol is uploaded.
Oct. 3: Yes! We got a gold medal in [http://igemvalencia.questionpro.com Valencia's survery].
Oct. 1: Congratulation Anne! Happy Birthday.
Sep. 22: A lot of new info on the background page.
Sep. 16: We're featured in this months [http://intern.sdu.dk/enheder/natur/PerspektivMening/PerspektivMening3sept2009.pdf Perspektiv & Mening], a magazine at SDU.
Sep. 10: We got our 4-brick-part together. Wohu. Now we can start testing.
Aug. 26: [http://igem.sdu.dk/?p=314 Loading buffer on trail] at our blog. And we are getting ready to insert our different bricks into a backbone, yeah.
Aug. 25: More profiles on our team page.
Aug. 20: We updated the team page with most of our advisors.
Aug. 19: Wohu! Anna has returned after a five week trip to Africa where she helped deliver babies in Kenya. Good to have you back! Also we wrote about our [http://igem.sdu.dk/?p=307 ligation troubles on our blog].
Aug. 17: We updated the wiki with more protocols, our diary and changed the layout a bit.
Aug. 14: Julius left us to study at [http://www.northcarolina.edu/ University of North Carolina]. We miss you already, Mr. Misty Forrest Dragon!
Aug. 11: Kir's birthday! Happy birthday!
Check out the other teams
Be sure to check out all the other teams that are competing in this years iGEM.
Sponsors
[http://www.sdu.dk Check out University of Southern Denmark]
[http://www.dna-technology.dk/ Check out DNA Technology]