Team:CIDEB-UANL Mexico/safety riskanalysis
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Revision as of 18:29, 14 June 2014
Risk Analysis
Some parts of this text were edited. You can see and download the oficial PDF version of this document RIGHT HERE
Overview IGEM CIDEB 2014 considers biosafety as important as every other points of the iGEM competition. Because of this reason, the team decided to perform a Safety Risk Assessment focused on the project and in the lab practices needed to accomplish it. |
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Organism’s Description Escherichia coli (E. coli) is a large and diverse genus of bacteria belonging to the Enterobacteriaceae. Although most strains of E. coli are relatively harmless, some can potentially affect humans and animals. Pathogenic kinds of E. coli can cause diarrhea, along with urinary tract infections, respiratory illness and pneumonia, among other symptoms. E. coli can be commonly found in the digestive tract of humans and many animals. It plays an important role in the decomposition and absorption of certain nutrients in the intestine that the body cannot break down by itself and to also prevent the digestive track to be colonized by other harmful bacteria. E. coli are capable of both aerobic and anaerobic cellular respiration, which is a characteristic that allows them to live in both oxygen rich and oxygen poor environments, which has allowed them to thrive in a wide variety of ecosystems. As a prokaryote, E. coli bacterium has no organelles, and its genetic information is not enclosed in a nucleus. E. coli protective layer consists on a cell wall and a capsule that protects it from the outside, potentially harmful environment. E. coli goes through binary fusion on a regular basis if given the right conditions, usually at 37° Celsius, and it is able to thrive and reproduce at a very fast rate. As previously mentioned, E. coli is one of the most diverse genera of bacteria, probably due to its adaptive abilities. Although there is a wide variety of different E. coli strains to choose from, not all of them have the same characteristics; some of them are pathogenic and are not safe to work with, which is the main reason why during the practices at the team’s laboratory, the E. coli’s strain that was used is the K12 DH5-α strain, which is one of the safest strains to work with, and one of the most used in biotechnology research. The K12 DH5-α strain is characterized by its poor abilities to colonize plant and animal tissue, and a low resistance to outside-lab environment, temperature fluctuation and different media composition causing the organism to die. E. coli’s K12 DH5-α inability to colonize intestinal tissue was experimented in 1978 in a work made by R. Curtiss “Biological containment and cloning vector transmissibility” showing that the K12 DH5-α strain is not likely to behave as a pathogen in mammal tissue. Due to these previous mentioned characteristics, it is classified as a Class 1 Containment under the European Federation of Biotechnology guidelines, and according to the United States Environmental Control Agency (EPA) E. coli K12 DH5-α strain opposes a very low risk for other organisms and under contained conditions of fermentation and are safe to work with.
Figure 1: E. coli bacterium and its parts |
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Potential Risks
The Union module gives E. CARU the ability to bind glass and silica surfaces, which we will use in beads form with the presentation that is used commercially. No direct risks are related to the module itself, but Silica gel beads may contain toxic and potentially carcinogenic cobalt (II) chloride, which is added as a moisture indicator in commercially available product. This point is analyzed further in the “Union as a safety measurement” section. |
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Safety measures in the laboratory
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Potential Risks
The Union module gives E. CARU the ability to bind glass and silica surfaces, which we will use in beads form with the presentation that is used commercially. No direct risks are related to the module itself, but Silica gel beads may contain toxic and potentially carcinogenic cobalt (II) chloride, which is added as a moisture indicator in commercially available product. This point is analyzed further in the “Union as a safety measurement” section. |
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Safety measures in the laboratory
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Hazardous substances ● Ethidium bromide
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Union as a safety measurement
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Method for shutting down E.CARU Fig.10: Different types of UV rays. First of all, Ultraviolet or UV light is light with wavelengths from 100 to 400 nm. According to Meulemans in 1986, its spectrum is divided into 4 different categories, as the following table shows:
EPA (United States Environmental Protection Agency) states that disinfection by UV primarily occurs due to the germicidal action of UV-B and UV-C light on microorganisms. And that the germicidal action of UV-A light is small relative to UV-B and UV-C light. So, in order for UV-A light to cause a “shut off” effect in the organism, very long exposure times are necessary.
What UV light does to microorganisms is that, once absorbed, it modifies and damages irreparably the DNA of the organism on the matters of question, in this case E. coli K12, by causing a photochemical damage. Therefore, RNA and DNA, molecules in charge of storing and carrying genetic information, can’t function properly, causing it to lose the ability to reproduce. As Wolfe in 1990 states, and with the information from EPA, 254 nm is the most potent wavelength that can cause damage in DNA. 254 nm belongs to the UV-C light category and the team is planning to use it that way to deactivate E. CARU in extreme situations. The UV light already used in the project is a promoter of the Capture module. This promoter is activated by 360nm, so it belongs in the UV-A category, and as it was mentioned before, this does not cause damage to the bacteria in short periods of time. According to our project, UV is one of the easiest methods to shut off our GMO. |
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Conclusions |
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