Revision as of 04:00, 1 November 2017

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BALTIMORE BIO-CREW

Bio-Engineering E.Coli To Degrade Plastic and Save The Baltimore Inner Harbor

Design

This project started with only a few things in mind. Our team members knew they wanted to find a solution to an environmental issue that is prevalent in Baltimore City, and they wanted to develop a solution that could be created using the tools in the lab.

While researching solutions to the issue of plastic pollution, we found a paper describing a bacteria that could degrade PET plastic. This bacteria is known as Ideonella sakaiensis.

Found in Yoshida Sasuke's Lab, the bacterium Ideonella s. degraded the surface of a thin PET film at a rate of 0.13 mg/cm2/day at an incubation temperature of 30°C.

Two enzymes that were secreted onto film were believed to have aided in the almost complete degradation of the PET film. These enzymes are:

PETase (Esterase) :

catalyzes PET hydrolysis
Turns PET into MHET (Mono (2-hydroxyethyl) Terephthalate acid)

MHETase (Lipase) :

Breaks down MHET
Turns MHET into ethylene glycol and terephthalic acid.

Ethylene glycol and Terephthalic acid are used as energy source for I. sakaiensis.

We considered using the I. sakaiensis bacteria itself, but we decided that working with a newly discovered and relatively undocumented bacteria was too risky. So we had to find a safe and effective way of recreating something with the abilities of I. sakaiensis.

Instead of using the Ideonella sakaiensis bacteria to degrade plastic, we decided to insert the genes for plastic degradation into K-12 E.coli bacteria. We chose K-12 E. coli because it is safe to use, easily grown in the lab, and very well documented since it is commonly used.

Our Constructs

After obtaining the E.coli, we designed a construct, known as a biobrick, to allow the bacteria to express the proteins lipase and esterase that will degrade PET plastics.

First is the Lac Regulated Promoter, which starts transcription in the presence of lactose or IPTG. We chose a lac regulated promoter because we wanted to have better control over the expression of the two enzymes.

Secondly, we had the Ribosome Binding site which signals the start of translation from mRNA to protein.

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Difference between revisions of "Team:Baltimore Bio-Crew/Design"

Revision as of 04:00, 1 November 2017

BALTIMORE BIO-CREW

Bio-Engineering E.Coli To Degrade Plastic and Save The Baltimore Inner Harbor

Design

Our Constructs

Sponsers

The Baltimore Bio-Crew thanks our sponsors for their generous support of our team that made our project and travel to the Jamboree possible. Thank you!