Our project in a nutshell

Summary of our project

The 2014 EPFL iGEM team has been working on showing that biologically engineered organisms can detect and process signals quickly and efficiently. With this in mind, our team brought forward a novel idea: combining protein complementation techniques with biosensors to achieve fast spatiotemporal analysis of cell response to stimuli.

As a proof-of-concept, we aimed to develop the first BioPad: a biological trackpad made of a microfluidic chip, touch-responsive organisms and a signal detector. To make our organisms touch-sensitive, we engineering two stress-related pathways in E.Coli and S.Cerevisiae. In E.Coli, we engineered the Cpx Pathway - a two-component regulatory system responsive to envelope stress. In S.Cerevisiae, we modified the HOG Pathway - a MAPKK pathway responsive to osmotic stress. To learn more about the various components of our project, check out our overview section. If you are a judge, you might also be interested in our data page.

Envelope stress responsive bacteria

Can't touch this

Microfluidics

Our Biopad is implemented in a microfluidic chip. This tool allows all kinds of analytical experiments and is increasingly used in biological research. From fabrication to applications, find out more about this awesome device here!

Yeast

Discover how we took advantage of the HOG osmotic response pathway to create touch sensitive yeast strains! Learn more on how we implemented a split GFP and a split Luciferase in S.Cerevisiae leading to light emission when pressure is applied.

I.T

I like turtles.

Human practice

Are we human, or are we dancers ?

Safety

work in progress

MEET OUR TEAM

We are a group of 14 students from the faculties of Life, Biomechanical, and Computer Sciences, and are supervised by 2 EPFL professors, 1 Lecturer and 5 PhD students.

Team:EPF Lausanne

From 2014.igem.org