Team:NTU-Taida/Human Practice/Safety-in-iGEM
From 2012.igem.org
Safety in iGEM
Contents |
2012
2011
Imperial College London
The team Imperial College London wanted to protecting the soil from erosion. To achieve this, they design bacteria that would secret IAA, a hormone which would promote root growth. As the root growth faster after the seeds germinate, the ability for plants to hold soil will be enhanced, thus helping anchor the soil.
Since they’d like to introduce genetically modified(GM) bacteria into environment, they take the safety issue seriously. First, in their system, they design “Gene Guard” to prevent horizontal gene transfer. They engineered anti-holin into the genome, and holin and endolysin on plasmid. If horizontal transfer happens, accepted bacteria don’t have anti-holin to neutralize holing thus will be killed. Second, to make sure their project is practicable and safe, in human practice they have deal it from many prospect, including searching laws about GMOs. They also consulted many professors, such as social scientists, environmental scientists, plant experts and so on to ensure the safety of their idea. Last, they made a GM release guideline for future iGEM teams who may cope with the same problem. They aggregated their experience and wrote down many questions we need to carefully think about, and give some optional solution for them. This gives convenience to teams facing this situation.
IIT Madras
Team IIT Madras made a revolution on the selection method we use today. Instead of the traditional idea that use antibiotic resistance gene, they replace it by Proteorhodopsin(PR), a green-light driven proton pump. Cultured in minimal media, PR expression will provide energy advantage to plasmid owner, for PR gives the ability to use light as an energy source. Thus make a selective advange.
In this way, they overcame some disadvantage of using antibiotics. For example, avoiding the risk of horizontal antibiotic gene transfer and spread. Besides, this could reduce use of antibiotics on synthetic biology, because antibiotics are in fact toxins to the environment. And this would make a more environmental-friendly future.
Since Proteorhodopsin uses retinal as a chromophore for light reception, the supplied retinal is a key protein for the growth of the bacteria, hence people could give control to this system.
Gaston Day School
Team Gaston Day School try to build a nitrogen detector that is easy to use for needed people, like farmers and ranchers. They use RFP as reporter, thus simple to know if there is nitrogen pollution.
After the detection, the bacteria have to be destroyed in case the drug-resistant ability spread out. Rather than using complicated circuit or method, they choose to carry out a simple method – bleach. Amazingly, bleaching has a significant effect on killing bacteria. It seems can kill the bacteria completely. Once we follow the bleach direction could we use the bacterial detector or other modified bacteria safely.
They give us an example that we don’t always have to find out the solution from a sophisticated way. Sometimes simple, is the best.
2010
SDU-Denmark
Ideas of the project
The project of SDU-Denmark is “Flow-E”, which is a nano-scale machine that generates a flow by a bacterial pump. The bacteria were aligned along the internal surface of a mirco-tube, and the flow was generated through the synchronized movement of the flagella of the bacteria. The flow depends on the number of the flagella, and to alternate the flow, synthesis of the flagella was regulated by the intensity of light.
Thus, the project may be divided into three parts: retinal biosynthesis, phototaxis by photosensors and hyperflagellation, which will be combined into bacteria eventually. Phototsensors are activated by the light, and the signal transduction pathway was then started and linked to the synthesis of flagella, resulting in hyperflagellation. Retinol acts as a relayed component that initializes the signal transduction.
Safety concerns of their project
The safety concerns of the project was divided into three parts: (1) project and researcher safety (2)laws and guidelines (3)watermark.
#Project and researcher safety
During the election of the project, numerous ideas were considered by the team: the environment, foods, health & disease, physics/chemistry/biochemistry. First of all, they discussed about which bacteria it was possible to use. Medical ideas for implementing in the body were also considered. Secondly, which type of the actual mechanical work to be done tended to be a great issue. Pili were considered but then abandoned due to its virulent characteristics in some bacteria, which may lead to pathogenic consequences (ex: using pili of Pseudomonas aeruginosa, which is pathogenic to human body)
E.coli were considered because they are very well adapted to the laboratory environment, are easy to keep alive, can be fairly easy modified, and they no longer have the ability to thrive inside the intestines.
Furthermore, they have used their risk-assessment guidelines to describe the safety of each of our contributed parts, which included four dimensions and several related questions:<p/> <p style="text-indent: 2em;">General use-What type of lab should work with this BioBrick be done in?......etc.<p/> <p style="text-indent: 2em;">Potential pathogenicity-Does this BioBrick produce anything that plays an significant role in environmental processes?…. etc.<p/> <p style="text-indent: 2em;">Environmental impact-Does this BioBrick produce anything that plays an significant role in environmental processes?...... etc.
Possible malign use-Can your chosen host be arosoled? Does this BioBrick increase the host’s ability to vaporize?……etc.
Each part was accomplished by BLASTed the sequences of their parts, searching for the function and homologs of the pars, considering and assessing the questions mentioned earlier. Among all parts, only hyperflagellation part was considered to increase the pathogenicity of bacteria. However, the bacteria they chose are unable to survive and reproduce outside of laboratory conditions.
#Laws and guidelines
- Risk assessment:_
Based on the current UN and Denmark rules and law for genetically modified microorganisms (GMM's), risk-assessment was developed by listing some questions as assessment factors for evaluation, so that they can judge if our use of GMM's poses a threat towards the well-being or safety of human beings, animals, plants, or the environment.
- Substitution:_
In a suitable system, compatible with the intended work, that is safer for humans, animals and plants, or the environment is always significant, which might be achieved by substituting the other, more dangerous system. In their study, though the E.coli strain they used (MG1655 and TOP10 strains) was harmless, issues of substitution was also taken into consideration due to the laws and guideline in UN and Denmark.
- Assessment by local bio-safety group:_
Al the members of their team attended laboratory safety course from the Committee for Students’ Laboratory Safety to ensure everyone knew basic safety precautions before entering laboratories. For their project, all the experiments were done in security level 1 laboratories, and no pathogenic bacteria were used.
They also had interview with a representative of “Arbejdsmiljogruppen” , the local bio-safety group associated with the University of Southern Denmark. During the interview, they explained the details of the project, asked several questions about the biosafety(ex: if there would be increased risk due to work performed by relatively inexperienced students, or if they perceived any danger should the bacteria get out of the lab……), and get the replies about the safety from the representative to ensure the biosafety of their project.
#Watermarks
Watermarks are special sequences that were like a license. They are easy to find, easy to read and easy to insert by the developing team. They must be persistent in the plasmid, in order to recognized by other researchers in case it contaminates the environment or are accidentally transmitted to other labs. In conclusion, they chose to divide the code into two separate parts, each is from 6 to 26 nucleotides. Two equally long parts at each end of the coding sequence ensures symmetry , which again should help make insertion of a watermark easy, as this will reduce the complexity of the primers we need to design to insert them.Moreover, this ensures that identification is done easily, since the combination of nucleotides of the sequence from E to X and from S to P is known.
VT-ENSIMAG Biosecurity
Ideas of the project
safety