Team:LMU-Munich/Project/BioBrickBox

From 2014.igem.org

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Revision as of 20:13, 17 October 2014

 

BioBrickBox

In 2012, the iGEM-team LMU-Munich began the task to develop essential BioBricks, like vectors, promoters, reporters and affinity tags, especially suited for the use in Bacillus subtilis in order to establish a new chassis in the Escherichia coli-dominated world of iGEM. Even after the finals of the iGEM competition in 2012, the project was pursued further since its importance for synthetic biology and resulted in a publication in the Journal of Biological Engineering about this so called [http://www.jbioleng.org/content/7/1/29 Bacillus BioBrick Box].

This year, our team aims to enhance the Bacillus BioBrick Box by adding new parts, like different colored fluorescent proteins or a whole new cloning strategy.

Resistance Free Cloning

With BaKillus as an medical application it is most likely that it will be released - though in small amounts - into the environment. Therefore we sought after a solution in order to keep the final BaKillus free of unnecessary antibiotic resistances. In order to do so we developed a resistance free gene insertion strategy for integrative Bacillus subtilis vectors.

The upp gene from Bacillus subtilis W168 encodes for a Uracilphosphoribosyl transferase (UPRTase). Its key reaction in uracil salvage is the reaction of a uracil molecule with a 5'-phosphoribosyl-a-1- pyrophosphate (PRPP) molecule, resulting in the formation of UMP. A second locus, the pyrR Gene, encoding a second UPRTase has been identified. However it has been shown, that the UPRTase derived from pyrR locus has an influence on overall UPRTase activity of < 1 %. (J Martinussen, P Glaser, P S Andersen and H H Saxild J. Bacteriol. 1995, 177(1):271. ) This makes the upp-derived UPRTase the only physiologically relevant catalyst for UPRTase activity. Exposure to the pyrimidine analogue 5-Fluorouracil UPRTase results in production of 5-fluoro-dUMP, a very potent inhibitor of the thymidylate synthase (Neuhard, J. (1983) Utilization of preformed pyrimidine bases and nucleosides. In Metabolism of Nucleotides, Nucleosides and Nucleobases in Microorganisms. Munch- Petersen, A. (eds). New York: Academic Press, pp. 95– 148. ). As a result 5-FU is toxic to the Bacillus subtilis W168 strain. B. subtilis 5FU-resistant (5FUR) mutants selected on low drug concentration (10 mM 5FU) are UPRTase-defective. (Nygaard, P. (1993) Purine and pyrimidine salvage pathways. In Bacillus Subtilis and Other Gram-Positive Bacteria: Biochemistry, Physiology, and Molecular Genetics. Sonenshein, A.L., Hoch, J.A. and Losick, R., (eds). Washington, DC: American Society for Microbiology, pp. 359–378. ) This has made upp a go to choice for negative selection in combination with an B. subtilis W168 Δupp strain. So far it has been used to make clean in-frame deletions and point mutations. (A new mutation delivery system for genome-scale approaches in Bacillus subtilis Céline Fabret,† S. Dusko Ehrlich and Philippe Noirot* Génétique Microbienne, INRA, Domaine de Vilvert, 78352 Jouy en Josas Cedex, France. )

However, to our knowledge, no application using upp for clean insertions has been established so far.

The I-SceI Restricition endonuclease has a highly specific recognition sequence of 18 nucleotides. No such sequence is present in the W168 strain. It creates a double strand break at targeted location, which leads to an increased rate of repair at the specific site. By this, the rate of homologous recombination is increased by an factor of 100x. (Establishment of a Markerless Mutation Delivery System in Bacillus subtilis Stimulated by a Double-Strand Break in the Chromosome Ting Shi1,2,3,4., Guanglu Wang1,2,3,4., Zhiwen Wang1,2,3,4*, Jing Fu1,2,3,4, Tao Chen1,2,3,4, Xueming Zhao1,2,3,4 )

The Plan was to restructure the BioBrick compatible, integrative Bacillus subtilis vectors [http://parts.igem.org/Part:BBa_J179000 pSB1C], [http://parts.igem.org/Part:BBa_J179001 pSB2E] and [http://parts.igem.org/Part:BBa_J179002 pSB4S] in a fashion that leads to deletion of the antibiotic resistance after insertion of a gene of interest has been made. Integration of those basic vectors is achieved via homologous recombination between the amyE/lacA/thrC locus and the corresponding up and down fragments on the vector. This leads to an insertion of the gene of interest within the RCF10 compatible multiple cloning site and the resistance for positive selection (CAM/MLS/Spec).

We wanted to add the upp-cassette, containing an I-SceIsite, as well as an additional up/down fragment to the vector. The desired vectors are presented in Fig. 1. The upp-cassette will allow negative selection in 5FU media. The contained I-SceI site will be cut by the I-SceI restriction endonuclease which is encoded on helper plasmid pEBS-cop1. (nochmal auf das paper verweisen) (Figure)

Cloning Strategy

LMU2014 BioBrickBox ResistanceFree Cloning Strategy.png

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Fluorescent Proteins

Fluorescent proteins (FPs) are important tools in research on a cellular or molecular basis and in the past years, many different FPs with very diverse qualities related to color, brightness, duration, bleaching, maturation time and other parameters were developed. Unfortunately, most of this FPs are optimized for use in E. coli, yeast or mammalian cells, and we aim to evaluate the properties of different FPs for the use in B. subtilis to enhance our Bacillus BioBrick Box even further.

Fluorescent Proteins are often derivates of the first described FP, GFP, which was isolated from the jellyfish Aequorea victoria. This protein is of typical barrel-shape, built from 11 ß-sheets and a chromophor in the middle of the barrel. This barrel structure is typical for fluorescent proteins, whether they derive from GFP or not. Other colors than green where developed by changing single amino acids in the chromophore of GFP (e.g.: Yellow: YFP and Cyan: CFP) or by analyzing fluorescent proteins from other organisms, like Discosoma striata, a coral, from which some of our red FPs, like dsRed derive. FPs are an important tool in today’s research, for example in order to study gene expression or the location of specific proteins in a cell or a whole organism. This is the reason, why we tried to establish some different colors of FPs for use in B. subtilis by evaluating them for the Bacillus BioBrick Box.
Seven different FPs (Table 1) where chosen and either obtained from the registry or from the AG Mascher. The BioBrick E1010 (DsRed) was mutated via site directed mutagenesis by overlap extension PCR in order to delete two AgeI-Restriction sites and make the BioBrick compatible for the Freiburg standard RFC25. This improved BioBrick is called [http://parts.igem.org/Part:BBa_K1351021 BBa_K1351021]

The BioBricks E1010 (DsRed) and K592100 (mTagBFP) where both provided with the necessary overhangs for the Freiburg standard, the other FPs where already provided with the proper restriction overhangs. These seven FPs where fused with a His-Tag ([http://parts.igem.org/wiki/index.php?title=Part:BBa_K823037 BBa_K823037]), each C- and N-terminal and cloned into the vector pBS0K-Pspac ([http://parts.igem.org/wiki/index.php?title=Part:BBa_K1351040 BBa_K1351040]) and transformed into B. subtilis.

The intensity and spectrum of the fluorescence was measured by a TECAN Plate Reader, kindly provided by the AG Leonhardt from the LMU.


Table 1: Used fluorescent proteins
BioBrick number Name Color Excitation Peak Emission Peak
BBa_K1351021 DsRed Red 584nm 607nm
BBa_K592100 mTagBFP Blue 399nm 456nm
BBa_K1159302 eCFP Cyan 439nm 476nm
BBa_K1159301 sYFP2 Yellow 515nm 527nm
BBa_K823039 gfpmut1 Green 395nm 509nm
BBa_K1351042 mcherry Red 587nm 610nm
BBa_K823029 mKate 2 Red 588nm 633nm



LMU14 FP Gesamtkonstrukt.png

Fluorescence of GFP under expression of promoter Pspac

The mutagenesis of the Biobrick E1010 was successful and confirmed by sequencing, the thus created Biobrick is called [http://parts.igem.org/Part:BBa_K1351021 BBa_K1351021]. The fusion with the His tags were also successfully conducted and confirmed by sequencing. The ligation into the vector pBS0K-Pspac was confirmed via Colony PCR and the transformation into B. subtilis was conducted successfully. The fluorescence of all of the proteins, however, proved to be not very good and often at the same level as the auto fluorescence of the B. subtilis wild type. The examination of the cells under a microscope revealed, that the promoter is not suited for this experimental set up, since the gene expression is very heterogeneous and rather low.


This problem will be solved by recloning the FPs into the vector pBS1C ([http://parts.igem.org/wiki/index.php?title=Part:BBa_K823023 BBa_K823023]) together with the xylose-inducible promoter Pxyl([http://parts.igem.org/wiki/index.php?title=Part:BBa_K1351039 BBa_K1351039]).

RBS

Ribosome Binding Sites (RBS) are essential for gene expression, since they are required for translation initiation. Much to our dismay, there used to be no Bacillus RBS in the registry. So we designed a broad-range RBS library for B. subtilis, aiming for maximum translation initiation rate space coverage.


RBS are short nucleotide sequences that are complemetary to the 3' end of rRNA, and thus are bound by the ribosome during translation initiation. The Ribosome Binding Site is usually found ~8 nucleotides upstream of the start codon in procaryotes. In B. subtilis the perfect consensus RBS is AAGGAGGGATA (Bba_K1351028).
Using the Salis lab's RBS calculator we calculated our RBS library with the sequence ARRRRRRGATA. The 7 RBS from this collection that were submitted as BioBricks (Bba_K1351028-BBa_K1351034) are the ones that offer the best coverage of translation initiation rate space, 1 being the optimal Bacillus RBS and 7 being the weakest.
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Hi there!

Welcome to our Wiki! I'm BaKillus, the pathogen-hunting microbe, and I'll guide you on this tour through our project. If you want to learn more about a specific step, you can simply close the tour and come back to it anytime you like. So let's start!

What's the problem?

First of all, what am I doing here? The problem is, pathogenic bacteria all around the world are becoming more and more resistant against antimicrobial drugs. One major reason for the trend is the inappropriate use of drugs. With my BaKillus super powers, I want to reduce this misuse and thus do my part to save global health.

Sensing of pathogens

To combat the pathogenic bacteria, I simply eavesdrop on their communication. Bacteria talk with each other via quorum sensing systems, which I use to detect them and trigger my responses.

Adhesion

The more specific and effective I can use my powers, the lower the danger is of provoking new resistance development. So I catch pathogens whenever I get hold of them and stick to them until my work is done.

Killing

Talking about my work - killing pathogens is finally what I am made for. In response to quorum sensing molecules of the pathogens, I export a range of antimicrobial substances leading to dissipation of biofilms and the killing of the targeted bacteria.

Suicide switch

When the job is done and all the bad guys are finished, you don't need a super hero anymore. So after fulfilling my work I say goodbye to the world by activating my suicide switch.

Application

Of course I'm not only a fictional hero, but a very real one. In two different prototypes, I could be used for diagnosis or treatment of pathogen-caused diseases. However, there is still a whole lot of regulational and economical questions that have to be answered before.

See you!

So now you know my short story - and it is time for me to return to my fight for a safer world. Feel free to take a closer look on my super powers, the process of my development or the plans for a medical application.