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From 2011.igem.org

Contents 1 Abstract 2 Overall project: Bacterial Dosimeter 3 Project Details 3.1 The Sensor 3.2 Part 2 3.3 The Experiments 3.4 Part 3 4 Results

Abstract

     Ionizing radiation and radiation pollution is an important environmental problem that not only affects those working around radiation facilities, but those dealing with the aftermath of widespread nuclear disasters such as those at the Fukushima Daiichi nuclear reactor or the Chernobyl reactor. Penn State’s team project will focus on using a genetic circuit introduced into E. coli bacterial cells, in order to rapidly detect and report the presence of harmful ionizing radiation. We are working to develop a robust and reliable biosensor which utilizes the lambda phage lytic-lysogenic switch coupled with a fast-acting reporter capable of producing an easily visible effect. We believe that the final construct may have the potential to rival current radiation detection methods, such as digital dosimeters.

Overall project: Bacterial Dosimeter

Radiation of one form or another is a constant presence throughout our every day lives. Radiation, or the transmission and absorption of energy over a given distance, has proven an invaluable technology useful in applications for everything from heating our food to diagnosing and treating diseases.

All types of radiation can be divided into two categories: non-ionizing and ionizing. Non-ionizing radiation (consisting of radio, micro, infrared, and visible electromagnetic waves) contains less energy and has a relatively small effect on living organisms that has only recently been studied. Ionizing radiation, however, contains a much greater amount of energy capable of ionizing atoms which can lead to harmful effects on living tissue. This category of radiation encompasses alpha and beta decay as well as neutron, X-ray, and gamma radiation.

     Our hope is that the basis of our biological dosimeter system will prove to be an effective genetic system capable of detecting harmful levels of radiation and relaying it to those working in the field or affected area. We envision our system not only being useful in such applications, but also being capable of further expansion and evolution through the expanding field of synthetic biology.

Project Details

The Sensor

The design of our sensor was based on the lambda phage lysogenic vs lytic switch. Optimally, the system would be activated in the presence of DNA damage due to radiation. For that reason, we utilized the lambda phage switch, which transitions from the lysogenic cycle to the lytic cycle when DNA damage is detected. The genetic circuit we designed focuses on the DNA damage-sensitive lambda phage lytic-lysogenic cycle switch followed by a rapid response reporter similar to the immobilized fusion enzyme system pioneered by the Imperial College of London 2010 iGEM team. An initial design of our system is illustrated below.

Under normal conditions, PRM is active, which transcribes the lambda repressor, cI + RBS. The lambda repressor binds to OR1 and OR2, repressing PR, which in turn inhibits the transcribtion of Cro and TEV.

Part 2

The Experiments

Part 3

Results

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