Team:Uppsala University/Project
From 2012.igem.org
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<p>Misuse and overuse of antibiotics are contributing factors to the severity of the problem, and it seems that we need new approaches to solve it. One approach to the problem is to keep developing new kinds of antibiotics, but unfortunately there is no certainty that we can keep up with the resistance development. We are fighting a never ending battle against bacterial evolution that we at the moment seem to be losing. An outside-the-box solution is to approach problem from the other way. Why don’t we try to make the bacteria sensitive to already developed antibiotics once again? This is our approach. We accomplish it by engineering silencing artificial small RNAs against the resistance genes.</p> | <p>Misuse and overuse of antibiotics are contributing factors to the severity of the problem, and it seems that we need new approaches to solve it. One approach to the problem is to keep developing new kinds of antibiotics, but unfortunately there is no certainty that we can keep up with the resistance development. We are fighting a never ending battle against bacterial evolution that we at the moment seem to be losing. An outside-the-box solution is to approach problem from the other way. Why don’t we try to make the bacteria sensitive to already developed antibiotics once again? This is our approach. We accomplish it by engineering silencing artificial small RNAs against the resistance genes.</p> | ||
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<td><p><b>Targeting resistance with sRNAs</b><br> | <td><p><b>Targeting resistance with sRNAs</b><br> | ||
The graphs below shows that it is possible to engineer small RNAs to lower the resistance of <i>Escherichia coli</i> against the antibiotic kanamycin. The three different sRNAs UU17, UU37 and UU55 all had significant effects compared to expression of a wild-type regulating sRNA. The left graph shows the kanamycin resistance of <i>E coli</i> carrying the AAC(6') gene on an F plasmid, while the right graph shows the kanamycin resistance of <i>E coli</i> carrying the clinical resistance plasmid pUUH239.2.</p><br> | The graphs below shows that it is possible to engineer small RNAs to lower the resistance of <i>Escherichia coli</i> against the antibiotic kanamycin. The three different sRNAs UU17, UU37 and UU55 all had significant effects compared to expression of a wild-type regulating sRNA. The left graph shows the kanamycin resistance of <i>E coli</i> carrying the AAC(6') gene on an F plasmid, while the right graph shows the kanamycin resistance of <i>E coli</i> carrying the clinical resistance plasmid pUUH239.2.</p><br> |
Latest revision as of 02:58, 27 October 2012
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Antibiotic resistance is a major global health problem. During the last couple of decades, antibiotic resistance has become increasingly problematic, and there is no doubt that new approaches to solve this problem at a technical level are needed to alleviate the problem. The data below is taken from the european center for disease prevention and control (ECDC) and shows the proportion of resistant isolates of Klebsiella pneumoniae in the member states of the European Union from 2000 to 2010. Misuse and overuse of antibiotics are contributing factors to the severity of the problem, and it seems that we need new approaches to solve it. One approach to the problem is to keep developing new kinds of antibiotics, but unfortunately there is no certainty that we can keep up with the resistance development. We are fighting a never ending battle against bacterial evolution that we at the moment seem to be losing. An outside-the-box solution is to approach problem from the other way. Why don’t we try to make the bacteria sensitive to already developed antibiotics once again? This is our approach. We accomplish it by engineering silencing artificial small RNAs against the resistance genes. | |||
Targeting resistance with sRNAs |
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Transcription-like effector nucleases
Improving the Registry of Standard Biological Parts | |||
Conclusions |
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Challenge
Background
Goal Earlier studies of how to design an artificial sRNA showed that there were unknown factors determining whether an sRNA would be effective in blocking translation or not. To find the optimal sRNA, a large randomised library of sRNAs was made to find sequences efficient enough to down regulate the antibiotic resistance with a combinatorial approach[1].
Constructing a randomized library of small RNAs In order to screen for small RNAs with an antisense region hybridizing in an silencing manner to the 5’ UTR of the antibiotic resistance gene AAC (6´), the randomized sRNAs were transformed into an E coli MG1655 strain carrying a reporter system containing the native 5´UTR of AAC(6’) followed by an additional 15 codons of the coding sequence of AAC(6’) translationally fused via a linker (J18922) to the yellow fluorescent protein SYFP2 (K864100). Since the reporter system and the sRNA library were on two different plasmids, two suitable plasmid backbones were chosen from different compatibility groups. To make the reporter system as similar to the expression levels of the natural resistance genes as possible, a low copy origin such as pSC101 (BBa_K864001) was required while the sRNA library used a medium copy backbone such as p15A. Unfortunately, the low copy backbones of the pSB4X5 serie in the registry did not display the predicted behavior of a low copy plasmid, henceforth the decision to construct new plasmid backbones that could meet our requirements was made Read more
A randomized antisense region of thirty bases resulted in an immense library of sRNAs, where the limiting factor was the transformation efficiency of or competent cells. To be able to find promising silencing sRNAs in this vast library, a Fluorescence Activated Cell Sorter (FACSAria II from BD) was used to sort out 20 000 cells that showed a downregulation of SYFP2 from a total of 10^7 cells.
The cells sorted based on lowered fluorescence were plated on selective agar plates and studied under UV light in order to screen for colonies containing a small RNA that had downregulated the SYFP2 gene. This was problematic due to radiative DNA-damage, but this problem was solved by switching to a Visi-Blue transilluminator, avoiding damage to the cells and also simplified future screening. Clones that showed lowered expression of SYFP2 were measured for fluorescence using flow cytometry. The fluorescence levels could be distinguished with a accuracy of just a few percent.
The plasmids that contained sRNA down regulating SYFP2 were purified and transformed into DH5alpha, and then purified again to ensure pure plasmid clones free from reporter plasmids. Finally, the isolated sRNA plasmids were transformed into a new reporter strain to validate the downregulation with flow cytometry The reporter system together with the native spot42 has been sent as parts to the registry. This is to give future iGEM teams the possibility to repress any gene by replacing the RFP region with the 5´UTR of the gene of interest. |
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LexA and MarR In addition to MarR, we could also use LexA to target the SOS response system required for repairing DNA damage. By isolating LexA from the MG1655 chromosome using PCR and subsequent mutagenesis we acquired LexA3 [2]. RecA is also involved in this system by activation with single stranded DNA which interacts with the LexA repressor to facilitate autoprotolysis (self-cleavage) of the repressor from the operator which then leads to SOS response. The LexA3 [2] mutation protects from cleavage by RecA, which in turn increases the repression of the DNA repair system. This leads to weaker SOS response to antibiotics and increased DNA damage which will increase sensitivity to antibiotics and cell death. These constructs are in separate vectors (pSB1C3) and will be tested separately by transformation of LexA3 and MarR(G95S) into a ciprofloxacin resistant strain (DA25189). Potential reduction of resistance can be measured with Etest (BioMerieux).
Through three separate site directed mutagenesis PCR reactions of the Tet inverter (BBa_Q04400) we intend to create mutant versions of the TetR unable to interact with tetracycline, and as a result less likely to release from its binding site, lowering the expression of TetA.
[1] Alekshun, M.N., Levy, S.B., 1999 Characterization of MarR Superrepressor Mutants. J Bacteriol 181, 3303–3306.
[2] Lin, L.L., Little, J.W., 1988 Isolation and characterization of noncleavable (Ind-) mutants of the LexA repressor of Escherichia coli K-12. J. Bacteriol. 170, 2163–2173. [3] Müller, G., Hecht, B., Helbl, V., Hinrichs, W., Saenger, W., Hillen, W., 1995. Characterization of non-inducible Tet repressor mutants suggests conformational changes necessary for induction. Nat. Struct. Biol. 2, 693–703. |
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Delivery of constructs The M13 phage is an well characterized bacteriophage that specifically targets E coli and is often used in recombinant DNA technologies. It inserts a single stranded circular DNA and hijacka the bacterial systems to replicate their own DNA to make more phages. It has been shown that it is possible to deliver synthetic DNA into a resistant E coli strain using a phage, making the host cell less antibiotic resistant. [1] The phage approach was demonstrated by Timothy et al 2009, where they inserted proteins LexA and OmpF in the phage M13 that we have also have worked with (see gene networks for explanation of the genes LexA and OmpF).The infected cells showed a decrease in antibiotic resistance. In the article they also tested to inject engineered phages in mice infected with antibiotic resistant bacteria and eight out of ten survived instead of one out of ten when not infected with phages. Conjugation is a process in bacteria that enables bacteria to share genetic information by spreading plasmids to each other. In E coli, conjugation is initiated when the donor bacteria develop pili that bind to the surface of the receiver bacteria. Through this pilus conjugative plasmids can be transferred to the receiver cell. It might be possible to use this functionality of conjugative plasmids to deliver our synthetic genes to resistant bacteria. We have not only manage to clone the ompF and LexA genes, but also constructed a super-repressing mutant of MarR (see Gene networks), all proteins targeting antibiotic resistance in different ways. It is very possible that we could see a synergistic effect on the decrease of resistance if you would combine these protein based approaches with our synthetic small RNAs in a phage or conjugative plasmid.
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Chromoproteins
Chromoproteins are orginally derived from corals or sea anemones. The expressed pigment can be seen by the naked eye and without any external tool, making them very useful as reporter genes. During iGEM 2011, Team Uppsala-Sweden contributed with chromoproteins to the registry. This year, we have contributed with an additional gene, aeBlue, and characterized two chromoproteins from last year.
Characteriation of promoters:
Scarless deletion - negative/positive selection:
New working low-copy backbones:
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