Team:British Columbia

From 2010.igem.org

Revision as of 19:06, 22 September 2010 by Ayjchan (Talk | contribs)

Blasting Away Biofilms

To disperse ''Staphylococcus aureus'' biofilms, our team is working to express an endogenous bacteriophage and biofilm matrix-degrading enzyme DspB under the control of the Agr quorum-sensing system.

Our Project Page

And The Award Goes To...

Here's a list of the things we've accomplished according to iGEM judging and awards criteria. "I won and I get to scream and jump a little. But I got to go back to work tomorrow" - Benicio Del Toro, Best Supporting Actor.

See Our Accomplishments

It's Human!

Stop by our human practices section! What do people on the streets think about synthetic biology? To show you, we have quirky promoter maps, a live forum and a fabulous art gallery. Come and leave us your thoughts and definition of synthetic biology.

Talk Play Love


We are 9 undergraduate students, 2 graduate advisors and 3 faculty advisors from various disciplines including Pharmacology, Physiology, the Life Sciences, Materials Engineering, Chemical and Biological Engineering, and Engineering Physics.

Get up close and personal!

With the aim of dispersing Staphylococcus aureus biofilms, our team is working to express an endogenous bacteriophage and biofilm matrix-degrading enzyme DspB under the control of the Agr quorum-sensing system. We are using existing BioBrick parts (the P2 promoter and AgrCA genes) as well as our own new DspB Biobrick part. We have also developd a new standard for working with bacteriophages.

Learn more at our Project page!

Our new and characterized Biobrick part is the biofilm matrix-degrading enzyme DspB. In addition, we have further characterized the existing promoter Biobrick parts, P2 and Pcon in Staphylococcus aureus.

For more details, visit our Parts page!

We have developed a model of biofilm population dynamics as affected by our engineered bacteriophage. Using this model, we are able to run simulations that predict outcomes of the system and construct informed hypotheses to test with our system.

Run a simulation at our Modeling page!

What are human practices? What are its goals? Gaze upon our promoter maps to see what people on the street think "Synthetic Biology" means. Browse through our art gallery and be inspired to think more deeply about the diverse issues of synthetic biology and genetic engineering. Join our various discussions about synthetic biology and its applications in the real world at our forum.

What are you waiting for?

Every sub-team has its unique story of success and heartbreak. What are most important are the invaluable lessons learned, the extensive trouble-shooting expertise gained, the bonds of friendship formed, and of course... the victories!

Come trace our steps...





The International Genetically Engineered Machine competition (iGEM) is the premiere undergraduate Synthetic Biology competition. Student teams are given a set of biological parts from the Registry of Standard Biological Parts. Over the summer, the teams use these parts and new parts of their own to build biological systems and operate them in living cells. Through this experience, undergraduate students gain insight into the research process of searching out information and protocols to come up with their own novel project (not to mention all the trouble-shooting expertise gained!). Graduate student advisors also get a taste of what it feels like to be a principal investigator or lab technician in terms of providing for and guiding the undergraduate students. Finally, in November, hundreds of iGEM teams gather at MIT to compete at the annual Jamboree!