Team:EPF Lausanne/test/ted

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Most sciences are able to detect and process signals in a fast and efficient way. Biology lacks this ability as signal detection and processing requires large amounts of time leading to potential inaccuracies and interferences from external sources. We aim to improve this and make signal induction faster and more accurate while designing an innovating new biological machine using protein complementation techniques.

As a proof of concept of this new way of viewing biology, this year’s EPFL iGEM team aims to build the first biological touchpad, hereafter referred as the BioPad, allowing users to control electronics in real time through living organisms.

On top of its potential use a touchpad, the BioPad will have several applications: deliver a cheap, fast, efficient, and accurate antibiotic screening system; as well as providing a new way for studying genes by allowing the study of the relationship between genes and their corresponding activating signals.

Project

The Bio Pad

Our biological Touch Pad will allow to control electronic devices by emitting light at the specific location where the Pad has been touched. Light emission is possible by engineering reporter proteins such as the firefly Luciferase, the Renilla luciferase, the Infrared fluorescent proteins, and even the superfolder GFP. We split the reporter proteins and fused them to an E.Coli endogenous protein involved in the regulation of extracytoplasmic stress. The protein of interest is CpxR, a component of the CpxA-CpxR two-component regulatory system.

On top of developing the biological components allowing fast response to stimuli, we engineered a small, cheap and easy to use “microscope” mainly made of a small camera to detect the position of the emitted light, process the information and instruct the associated electronic device that the user is touching the BioPad a given position.

The CpxA-R Pathway

The natural function of the CpxA­-CpxR two component regulatory system in bacteria is to control the expression of ‘survival’ genes whose products act in the periplasm to maintain membrane integrity. This ensures continued bacterial growth even in environments with harmful extracytoplasmic stresses. The CpxA-­CpxR two component regulatory system belongs to the class I histidine kinases and includes three main proteins:

CpxA
an integral inner­-membrane sensor kinase, which activates and auto­phosphorylates when sensing misfolded proteins in the E.Coli periplasm. CpxA transduces its signal through the membrane to activate the cytoplasmic CpxR response regulator by a phosphotransfer reaction.
CpxR
CpxA’s corresponding cytoplasmic response regulator belongs to the OmpR/PhoB family of winged­helix­turn­helix transcriptional response regulators and is phosphorylated by CpxA in the presence of extracytoplasmic stresses. Phosphorylation induces CpxR’s homo­dimerization, and activation as a transcription factor. Phosphorylated CpxR then binds to the promoters of genes coding for several protein folding and degradation factors that operate in the periplasm.
CpxP
an inhibitor of CpxA that we suspect to actively compete with misfolded proteins (CpxP is a chaperone).

Engineering: CpxR and split complementation techniques

The main component that we wish to engineer is CpxR. It has been reported that the protein homo-dimerizes upon activation. We thus plan to use fused split proteins of fluorescent and bioluminescent nature to detect its activation.

As a preliminary step, we used two fluorescent proteins sfGFP and IFP to characterisation CpxR. Split sfGFP (superfolder GFP) is an irreversible split system which will be used to prove the dimerization of CpxR. Split IFP on the other hand (Infrared Fluorescent Protein) is a reversible split system which will be used to understand the spatio-temporal dimerization of CpxR and thus allow us to better understand the On/Off mechanism of this system.

To achieve our final goal, we will engineer split bioluminescent proteins: Firefly and Renilla split Luciferases. These constructs will be the main component of our system. When fused to CpxR, we are expecting to witness emission upon touch.

Engineering: Microfluidic chip interface

Our specially designed microfluidic chip, hereafter known as BioPad Chip, will allow easy and accurate induction of fluorescent or bioluminescent signals. The chip is made up of thousands of compartments – representing the pixels of our device ­- of the height of a bacteria. The BioTouch Chip thus allows the effective trapping and induction of stress onto our engineered bacteria.

Engineering: The BioPad Detector

The signals induced by the BioTouch Chip are then processed by our self designed detection system: the BioTouch Detector. The BioTouch Detector is mainly made of a cheap computer (Raspberry Pi), a highly sensitive digital camera with appropriate light filters, and a light emitting source. The BioTouch Detector locates signals from various sources (infrared fluorescence, green fluorescence and luminescence), processes them and sends back the relative positions of the signals with respect to the BioTouch Pad. Thanks to this position, we are able to extract information such as giving a computer operating system that the position represents the position of the mouse on a screen, that the well at the given position is a suitable antibiotic candidate, or that a gene of interest has been activated. We therefore effectively control a computer or any other electronic device through a living interface: the BioTouch Pad.

Applications

The biopad is not the only application of our modified organisms and microfluidic devices.

Antibiotic screening device

Bacterial envelopes are often remodeled when encountering hosts. These changes lead to the synthesis of complex envelope structures that are important virulence factors. Improper assembly of these structures can harm the bacterial envelope and lead to Extracytosolic Stress. Bacteria counter the potential envelope stresses by downregulating these virulence factors.

Taking into consideration the close involvement of virulence factors and bacterial survival, the CpxA-R pathway has been shown to be a promising candidate as an antibiotic. When activated, the CpxA-R pathway activates a bacterial survival response which among other things, regulates and monitors the biogenesis of complex surface virulence factors such as pili/fimbiae and type III and type IV secretion systems. Equivalently, it has also been suggested that the CpxA-R system is involved in antibiotic mediated bacterial cell death. Our device would therefore allow us to detect and mesure activation of the CpxA-R system in real-time and thus assess the strength and influence of antiobiotics and antiobiotic candidates on the CpxA-R system.

The ultimate goal of this application would thus be to allow high-throughput screenings for antibiotic candidates enabling the removal of virulence factors from pathogenic bacteria. This would improve antibiotic treatment and serve as an “antibiotic complement”.

Another application to our BioPad organisms would be related to cancer. In modern research, tumor progression is fairly difficult to evaluate: most scientists rely on the size of a tumor to understand how developed it is. Our idea would be to integrate our engineered organisms within the tumor's cellular matrix (Matrigel) to allow researchers to be able to assess the progression of tumors by how luminescent the tumor is when a light emitting molecule -luciferin- is injected. This would allow scientists to reduce unnecessary animal sacrifices in tumor research.

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.

  • Ted Baldwin

    “I’m pretty confident that it should work.”

     

  • Içvara Barbier

    “010000110110111 101101110011011 100110000101110 01001100100”

     

  • Romane Breysse

    “I'll be 5/8 of an hour late”

     

  • Jin Chang

    Bachelor Life Sciences

     

  • Axel de Tonnac

    “I forgot to eat today”

     

  • Bastien Duckert

    "I can't do sh*t with I'm sorry"

     

  • Arthur Giroux

    * Insert one of his random and very strange quotes *

     

  • Nikolaus Huwiler

    “Imagine a world where technology is alive”

     

  • Sakura Nussbaum

    "Hello"

     

  • Lucie Petetin

    "Ooh, it's sooo cuuute"

     

  • Cécile Piot

    “The PCR didn't work... again”

     

  • Ione Pla

    “How about no”

     

  • Grégoire Repond

    Parafilm specialist

     

  • Thomas Simonet

    ''Oh no, there are no chocolate muffins left''

     

  • Maroun Bousleiman

    "This is my limit; look, I'm not smart, I'm not funny"

     

  • Oleg Mikhajlov

    "Is everything alright, guys?"

     

  • Ekatarina Petrova

    Thingy = coalenterazine

     

  • Rachana Pradhan

    "We [the TAs] also have a life!"

     

  • Antonio Meireles Filho

    Phd Life Sciences

     

  • Prof. Bart Deplancke

    "Make a list"

     

  • Dr. Barbara Grisoni-Neupert

    “Do you talk about iGem when you meet the guys?”

     

  • Prof. Sebastian Maerkel

    “I'm thinking about science”

     

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