Team:Calgary/Sandbox/Notebook/Journal/Reporter

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<h1>Ferritin Journal</h1>
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<h1>Reporter Journal</h1>
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<h2>Week 1: May 1 - May 3</h2>
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<h2>Week 1: May 1 - May 3</h2>
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<p>We examined three problems related to ferritin. Firstly, we investigated protein isolation of ferritin. We are considering the protocols created by Santambrogio et al. (1993), as they have been used by multiple other authors as well. This paper uses precipitation followed by column chromatography, and verification with spectroscopy, PAGE and SDS-PAGE (Levi 1994). Alternatively, we may consider using his-tags for Ni-NTA column purification.
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<p>This week we attended the appropriate safety courses required by our University to work in the lab. Besides that, the undergraduate supervisors presented about the principles of Genetics and Synthetic Biology to the new team members.</p>
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Secondly, we examined the feasibility of using magnetism to manipulate ferritin. Commercial horse spleen ferritin was tested on a magnetic Dynabead rack, and as expected, it did not move, as the core should not be magnetic. We must thus synthesize magnetoferritin wherein the native ferrihydrite core is converted to magnetite--a paramagnetic material which can be attracted to magnetic fields (Jordan et al. 2010, Wong et al. 1998). We were able to attain some general knowledge of magnetism in nano-scale material, including a basic understanding of blocking temperatures, superparamagnetism and magnetic moments, all magnetism-related measurements. But we are ill-equipped to model this system theoretically in terms of calculated forces. We also explore the possibility of alternative magnetic particles, in the case ferritin is too small to exhibit magnetic forces significant enough to move proteins. Magnetosomes were found to be much larger, but unviable due to the complexity of their creation. The CCMV virus may also be an option, although there is currently little known about it and therefore further research into this topic is required. (Lohsse et al. 2011).
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Because we also intend to scaffold proteins to ferritin as in our TALE DNA-binding proteins, we looked into fusions to both C- and N-terminals of ferritin. The N- and C- termini of ferritin subunits are present on the outside and inside of the nanoparticle respectively, and therefore N-terminal fusions are an obvious choice to ensure TALEs are present on the exterior of the nanoparticles (Dorner et al. 1985).
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<h2>Week 2: May 6 - May 10</h2>
<h2>Week 2: May 6 - May 10</h2>
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<p>This week we participated in a general molecular biology workshop to refresh our memory of techniques used in molecular biology.</p>
<h2>Week 3: May 13 - May 17</h2>
<h2>Week 3: May 13 - May 17</h2>
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<p>We continued the molecular biology workshop. This week we also divided up into our respective groups for the project and decided research priorities.</p>
<h2>Week 4: May 20 - May 24</h2>
<h2>Week 4: May 20 - May 24</h2>
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<p>We examined three problems related to ferritin. Firstly, we investigated protein isolation of ferritin. We are considering the protocols created by Santambrogio et al. (1993), as they have been used by multiple other authors as well. This paper uses precipitation followed by column chromatography, and verification with spectroscopy, PAGE and SDS-PAGE (Levi 1994). Alternatively, we may consider using his-tags for Ni-NTA column purification.
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<p>
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Secondly, we examined the feasibility of using magnetism to manipulate ferritin. Commercial horse spleen ferritin was tested on a magnetic Dynabead rack, and as expected, it did not move, as the core should not be magnetic. We must thus synthesize magnetoferritin wherein the native ferrihydrite core is converted to magnetite--a paramagnetic material which can be attracted to magnetic fields (Jordan et al. 2010, Wong et al. 1998). We were able to attain some general knowledge of magnetism in nano-scale material, including a basic understanding of blocking temperatures, superparamagnetism and magnetic moments, all magnetism-related measurements. But we are ill-equipped to model this system theoretically in terms of calculated forces. We also explore the possibility of alternative magnetic particles, in the case ferritin is too small to exhibit magnetic forces significant enough to move proteins.
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<p> Magnetosomes were found to be much larger, but unviable due to the complexity of their creation. The CCMV virus may also be an option, although there is currently little known about it and therefore further research into this topic is required. (Lohsse et al. 2011). </p>
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<p>
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Because we also intend to scaffold proteins to ferritin as in our TALE DNA-binding proteins, we looked into fusions to both C- and N-terminals of ferritin. The N- and C- termini of ferritin subunits are present on the outside and inside of the nanoparticle respectively, and therefore N-terminal fusions are an obvious choice to ensure TALEs are present on the exterior of the nanoparticles (Dorner et al. 1985).
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<h2>Week 5: May 27 - May 31</h2>
<h2>Week 5: May 27 - May 31</h2>
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<p>While we are unsure of exactly how ferritin will be used in our project, any capacity in which we use it requires isolating recombinant ferritin from E. coli. We investigated which terminus to locate purification tags (eg, His tags) on ferritin subunits. Ingrassia et al. (2006) found that small amino acid additions to the C-terminus of either heavy or light chain ferritin are not deleterious to its function. Thus, we are contemplating fusing proteins to the N-terminal of ferritin as discussed last week, and using the C-terminus for tags to isolate recombinant subunits.  
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<p>While we are unsure of exactly how ferritin will be used in our project, any capacity in which we use it requires isolating recombinant ferritin from E. coli. We investigated which terminus to locate purification tags (eg, His tags) on ferritin subunits. Ingrassia et al. (2006) found that small amino acid additions to the C-terminus of either heavy or light chain ferritin are not deleterious to its function. Thus, we are contemplating fusing proteins to the N-terminal of ferritin as discussed last week, and using the C-terminus for tags to isolate recombinant subunits. </p>
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We also contemplated methods for controlling expression in terms of proportions of H and L subunits in completed ferritin. This could influence iron dynamics of completed ferritin. Lee et al. (2002) overcame this issue by fusing the heavy and light chains together to ensure that completed nanoparticles have a 1:1 ratio of each subunit. We are trying to determine pitfalls of this expression strategy. Finally, we investigated methods for validating nanoparticle formation. Namely, we considered fluorescence spectroscopy as tested by Parker et al. (2008), where 410nm output was indicative of iron incorporation as per assembled ferritins.
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<p>
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We also contemplated methods for controlling expression in terms of proportions of H and L subunits in completed ferritin. This could influence iron dynamics of completed ferritin. Lee et al. (2002) overcame this issue by fusing the heavy and light chains together to ensure that completed nanoparticles have a 1:1 ratio of each subunit. We are trying to determine pitfalls of this expression strategy. Finally, we investigated methods for validating nanoparticle formation. Namely, we considered fluorescence spectroscopy as tested by Parker et al. (2008), where 410nm output was indicative of iron incorporation as per assembled ferritins.
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<p>
Apart from using magnetism to manipulate magnetoferritin to isolate pathogenic DNA, we developed a backup approach. Watt et al. (2012) constructed a nanoscale battery where ferritins with two different cores were oxidized and reduced on gold electrodes. We are contemplating using a split TALE capture system to bring ferritin into close association of an electrode. Current could then flow from ferritin into an electrode to indicate binding of pathogenic DNA.
Apart from using magnetism to manipulate magnetoferritin to isolate pathogenic DNA, we developed a backup approach. Watt et al. (2012) constructed a nanoscale battery where ferritins with two different cores were oxidized and reduced on gold electrodes. We are contemplating using a split TALE capture system to bring ferritin into close association of an electrode. Current could then flow from ferritin into an electrode to indicate binding of pathogenic DNA.
Finally, we considered how we might construct a magnetic device to isolate ferritin. Bushart et al. (2006) discussed method for isolating metal chelating magnetoferritin for metal purification. However, the necessary magnetic field strengths, mesh density, or mass of isolated compounds in these systems were not explicit. Thus, we are still uncertain about the feasibility of using magnetism to isolate proteins attached to magnetoferritin.
Finally, we considered how we might construct a magnetic device to isolate ferritin. Bushart et al. (2006) discussed method for isolating metal chelating magnetoferritin for metal purification. However, the necessary magnetic field strengths, mesh density, or mass of isolated compounds in these systems were not explicit. Thus, we are still uncertain about the feasibility of using magnetism to isolate proteins attached to magnetoferritin.
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<h2>Week 6: June 3 - June 7</h2>
<h2>Week 6: June 3 - June 7</h2>
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<p>The application of ferritin in our project has changed substantially. Due to uncertainties of using magnetism to isolate proteins attached to ferritin, our team proposes instead to use it as a nanoscale protein scaffold. Our team was inspired by the work of <b> REFERENCE </b> et al. (2011) who used gold nanoparticles bound to ssDNA to detect DNA in a lateral flow strip assay.
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<p>    We have decided to modify the aforementioned system. We’ll replace gold nanoparticle with ferritin and ssDNA with TALEs targeted to pathogenic E. coli markers. These nanoparticles will bind pathogen DNA via TALEs, be drawn up through a strip via capillary action, and become immobilized with complementary TALEs affixed to other regions on the strip. A reporter marker will also be fused to the recombinant ferritins to allow visualization of the pathogenic DNA.
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This system is unique since double stranded sample DNA could be detected without having to first melt the DNA. Cheap prototypes for such a system could be constructed and would be suitable for cost constraints in the beef industry. Moreover, this system is amenable to scale-up for the identification of multiple pathogenic markers on a single lateral flow strip. We are, however, unsure as to what to use as a reporter enzyme.
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We also met with two U of C professors in nanoscience to discuss the feasibility of our magnetism idea. Dr. Max Anikovskiy, an instructor from the nanoscience program, allowed us to use a 50 lb. pull force rare earth magnet to manipulate native horse spleen ferritin. However, there were no changes over a three hour period. We also spoke to Dr. Simon Trudel from the nanomagnetism research group. He seemed to think our idea was feasible, but might require optimizing with respect to the solvent system in which the particles are dissolved. From both these meetings, it emerged that modelling the fluid dynamics is beyond our capabilities. Our best bet is to test these ideas experimentally, one step at a time, by first synthesizing and testing magnetoferritin.
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<b> MAKE A FIGURE OF LATERAL FLOW STRIP</b>
<h2>Week 7: June 10 - June 14</h2>
<h2>Week 7: June 10 - June 14</h2>
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    <p>   We visited the Cargill Meat Solutions plant and discovered that our system would be most applicable in identifying cattle who are super shedders, which would require our system to be quantitative. One possible approach utilizes a fusion of TAL and a reporter protein, although this system may subtract from quantification due to binding of multiple DNA strands to the nanoparticle.FIGURE?? An alternative approach utilizes a ferritin-TAL to immobilize target DNA, which can then be visualized through a second TAL fused to a reporter enzyme. FIGURE??
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            One question we currently have is in the construction of the ferritin genes.  Lee et al. (2002), and Huh and Kim (2003) have successfully created heavy-light chain ferritin subunit fusions, allowing better control of the subunit ratios. Therefore we intend to use a similar approach as it would halve the number of subunits involved, and in turn halve the number of bound TALs, reducing our concerns about steric hindrance. E-coils will be bound to the N-terminus due to its presence on the outside of the nanoparticle,  ensuring exposure to the environment (Luzzago and Cesareni 1989).
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            Upon further investigation, we found that the creation of Prussian Blue ferritin nanoparticles involve the use of potassium ferrocyanide, a compound that has the potential to evolve hydrogen cyanide. These fears were abated upon contacting members in the nanoscience department, stating the conditions and concentrations involve in our experiment were too low to be of concern.
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<h2>Week 8: June 17 - June 21</h2>
<h2>Week 8: June 17 - June 21</h2>
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An issue we addressed this week was the assembly of gene constructs to test ferritin in our system. A tentative strategy plan has been proposed. Coordinating this plan with the TALE and linker teams is necessary to ensure compatibility among the many components of this project. Upon receiving commercially-synthesized genes, we will order primers to use the Golden Gate assembly method.
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To test whether the synthesis of magnetoferritin is successful, we must first synthesize it using the method proposed in week 4, where the native ferrihydrite core is converted to apoferritin then magnetite. Using a magnet with a relatively strong pull force (about 50 lbs.), we hope to see the magnetoferritin respond in solution.
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We must also confirm the applicability of using ferritin as the Prussian blue reporter system. After generating ferritin with a Prussian blue ferrihydrite core, we will manipulate the core type, pH, coloured substrate, and temperature to test the feasibility of this method. If these tests are futile, we may need to develop an enzymatic reporter that will function in parallel with our system. The necessary materials have been obtained for these experiments, and results will follow shortly.     
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<h2>Week 9: June 24 - June 28</h2>
<h2>Week 9: June 24 - June 28</h2>
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<p>In order to use beta-lactamase as a potential reporter system it was necessary to use designed primers to PCR out the gene from the backbone of the <a href="http://parts.igem.org/Part:pSB1A3">pSB1A3</a> plasmid (it is present here as it conveys ampicillin resistance). Three primers were designed in order to retrieve the beta-lactamase gene just by itself as well as having it with a His-tag in order to aid with protein purification. After the PCR was performed the resulting DNA was run on a gel to confirm the gene size (Figure 2). This PCR appeared to be successful based on size (900-bp and 927-bp for the beta-lactamase and beta-lactamase with His-tag respectively) but after sequencing it was determined one of the primers contained a design error resulting in a truncated gene. The primers will be redesigned in order to successfully achieve the extraction of the beta-lactamase gene from the pSB1A3 plasmid.</p>
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<img src="https://static.igem.org/mediawiki/2013/0/0b/UCalgary2013TRJune26thbetalacprimer.png" alt="Beta-lactamase PCR Extraction" width="800" height="447">
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<p><b>Figure 2.</b> PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. 5 out of the 8 lanes for the beta-lactamase extraction display bands at approximately 900-bp which is expected as the part should be 909-bp. All of the lanes for the extraction that includes the His-tag show bands at that are a similar size compared to the normal beta-lactamse extraction which is expected as the gene is 927-bp in size. Some unexpected amplification is seen for this PCR set. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour. </p>
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<h2>Week 10: July 1 - July 5</h2>
<h2>Week 10: July 1 - July 5</h2>
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<h2>Week 11: July 8 - July 12</h2>
<h2>Week 11: July 8 - July 12</h2>
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Our team reviewed primers design for our Golden Gate Assembly with emphasis on ensuring proper ligation of our products. This involved matching melting temperatures, ensuring there were no palindromic sequences, and considering the other requirements involved. Primer design is integral to our overall project since we must successfully use Golden Gate Assembly to synthesize our parts. Much of our time has been spent towards this goal.
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Also, Ferritin gene sequences have arrived. We have transformed, MiniPrepped and ready as a template for the Golden Gate primers.
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<p>Also received this week were the redesigned primers for extracting beta-lactamase from the <a href="http://parts.igem.org/Part:pSB1A3">pSB1A3</a> plasmid. These primers were used in three combinations to produce the beta-lactamase gene by itself, the beta-lactamase gene with a His-tag at the end and a beta-lactamase gene with a flexible glycine linker (<a href="http://parts.igem.org/Part:BBa_K157013" >BBa_K157013</a>) fused to the N-terminus of the protein. The gels of these PCRs indicated that the experiment was successful (Figures 6, 7).  These products were PCR purified in order to be used for constructions.</p>
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<img src="https://static.igem.org/mediawiki/2013/a/aa/UCalgary2013TRJuly8pcrblac1.png" alt="Beta-lactamase PCR Extraction Attempt Two" width="786" height="381">
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<p><b>Figure 6.</b> PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. Every lane for the beta-lactamase extraction display bands at approximately 900-bp which is expected as the part should be 909-bp. All of the lanes for the extraction that includes the His-tag show bands at that are a similar size compared to the normal beta-lactamse extraction which is expected as the gene is 927-bp in size. Some unexpected amplification is seen for this PCR set. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour.</p>
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<img src="https://static.igem.org/mediawiki/2013/8/83/UCalgary2013TRJuly8pcrblac2.png" alt="Beta-lactamase with Linker PCR Extraction" width="642" height="381">
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<p><b>Figure 7.</b> PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. Expected band sizes were seen for all of the extractions at approximately 950-bp. Some unexpected amplification is seen for this PCR. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour</p>
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<p>A construction that was attempted this week consisted of placing the beta-lactmase gene with a His-tag behind the promoter <a href="http://parts.igem.org/Part:BBa_J04500">BBa_J04500</a>. Also attempted were plasmid switches of the three beta-lactamase genes extracted via PCR. Colonies were seen for all of the transformed ligation mixtures for these constructions. Colony PCR of these transformed colonies only produced potentially viable results J04500 + Beta-lactamase (with His-tag) construct.</p>
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<h2>Week 12: July 15 - July 19</h2>
<h2>Week 12: July 15 - July 19</h2>
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    The primers for golden gate assembly arrived this week and we conducted the PCRs required for our first attempt at making our constructs. The final ligation product was run on a gel and appears promising, showing a 1500bp band, most likely representing our construct. Despite this, transformations have failed and therefore we have to look back at our primers and experimental design.
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    We now have a more set idea of how we’re going to synthesize magnetoferritin. We will most likely be using a flask with a rubber stopper that will allow inflow and outflow of the nitrogen gas, which will be bubbled into the solution with an air stone. Nitrogen is free to exit a small port in the stopper and reagents can easily be added via injection through the rubber stopper. Safe handling of the thioglycollic acid is paramount, therefore equipment has been ordered (elbow-length gloves, respirator, apron, and something else), and attempts at synthesis will be conducted as soon as we get the equipment.
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<p>The beta-lactamase construction attempted last week proved to be unsuccessful however another construction from this week did produce a gene that appeared to be the J04500 + Beta-lactamase with a His-tag part. This construction was sent in for sequencing over the weekend.</p>
<h2>Week 13: July 22 - July 26</h2>
<h2>Week 13: July 22 - July 26</h2>
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<p>The sequencing of the J04500 + Beta-lactamase with a His-tag construction from last week revealed that we had successfully completed this part.Mutagenesis primers were designed for this gene as a BsaI cut site is present in the sequence which could interfere with any Golden Gate assembly attempted with this part. Successful mutation of this part was completed and confirmed via gel electrophoresis and sequencing. A preliminary test was also attempted with this part in order to see if the leaky properties of the LacI (BBa_J04500) promoter could successfully produce beta-lactamase at levels large enough to allow the transformed cells to survive on plates containing ampicillin even though this part exists in a chloramphenicol resistant plasmid (pSB1C3). This test successfully displayed that active beta-lactamase was being produced by our cells. Also produced this week was the plasmid switch of the beta-lactamase gene with a His-tag at the C-terminus, the beta-lactamase gene with a glycine linker at the N-terminus.</p>
<h2>Week 14: July 29 - August 2</h2>
<h2>Week 14: July 29 - August 2</h2>
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    Realizing the time constraints we have for the submission of our parts, we reviewed our Golden Gate assembly experiment to ensure we can submit the parts to the registry. In case this method fails, we also began development of Gibson assembly primers to see if this assembly assembly method cooperates with us.
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    We began characterization of prussian blue ferritin through kinetics experiments. Our first goal was the construction Michaelis-Menten plot to determine the activity of our peroxidase-like catalyst with the 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS) substrate which ended up looking like this: <b> INSRERT GAPHHHH </b> These experiments then continued on to optimization experiments wherein we determined the optimal pH, temperature, and concentrations of ABTS and H2O2. We intend to repeat these experiments 3,3',5,5'-tetramethylbenzidine so that we could compare the two substrates and determine the most viable one for our final system.
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<h2>Week 15: August 5 - August 9</h2>
<h2>Week 15: August 5 - August 9</h2>
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Prepared the basic reagents for magnetoferritin synthesis, we attempted to create apoferritin this week. Apoferritin turned out to be very light brown, suggesting some of the iron cores were unloaded. Moved onto magnetoferritin synthesis, but the resulting product contained a lot of particles in it, we fear this may be due to synthesis of magnetite crystals in addition to magnetoferritin.
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    We did our tested heavy ferritin as ordered from the synthesis company for expression on an SDS-PAGE. The J04500 LacI induced promoter was induced with 0.8mM IPTG for four hours at 0.6OD for the cultures. The protein was either not expressed or was too difficult to distinguish from the background proteins in the cell. Protein trials will be repeated once we assemble construct two in iGEM’s pSB1C3.
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Also continued on with the ABTS kinetics experiments. We were able to create graphs showing the effectiveness of our catalyst under varying pH.
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<b> GAPHPPHPHPH </b>
<h2>Week 16: August 12 - August 16</h2>
<h2>Week 16: August 12 - August 16</h2>
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    Finished off the ABTS kinetics experiments for prussian blue ferritin, which involved finding the optimal temperature for the reaction. But the spectrophotometer available to us is limited to 25-45C. This limitation is still within our expected prototype temperature and therefore it is not a big worry. We will then continue on with determining the kinetics for TMB and find out which substrate is better for our system.
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<h2>Week 17: August 19 - August 23</h2>
<h2>Week 17: August 19 - August 23</h2>
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Due to multiple failures of the plasmid switches of both ferritin and other parts, we conducted tests on multiple aspects of our procedures, including ligase, phosphatase and buffer. None of these parts were determined to be problematic, therefore we attempted higher DNA concentrations on controls, which worked. Therefore we will attempt the plasmid switch of the ferritin parts at some other time.
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    We also began initial tests with TMB, but realized our stock concentrations were at 1mg/mL. As these results would be incomparable to our ABTS experiments, which were at 10mg/mL, we remade the TMB stock solution to 10mg/mL and redid the experiments.
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<h2>Week 18: August 26 - August 30</h2>
<h2>Week 18: August 26 - August 30</h2>
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Our first attempts at observing one of our fusion proteins on SDS-PAGE were conducted, although the bands do not appear to contain the protein. We’ve read about a technique that can stain iron, which is essentially the same as the creation of Prussian Blue ferritin. Using this method we could exploit the iron core of ferritin by running a native PAGE and staining the iron core. This would then confirm the presence of our protein, therefore we ran initial tests of this method by running dilutions of the ordered ferritin solution in addition to other things. This method worked extremely well for staining ferritin controls, although the <i>E.coli</i> samples lack the bands, which is problematic as this indicates  either there is no ferritin being produced, or this stain isn’t sensitive enough for the amount of ferritin produced. <b> FIGRUERUEURE </b>
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    On a happier note, our work with gibson assembly has finally produced one of our constructs, the fusion of the heavy and light ferritin chains to an E-coil. Because this method appears to be relatively successful, we intend to order more primers and use Gibson assembly for the construction of other parts as well.
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<h2>Week 19: September 2 - September 6</h2>
<h2>Week 19: September 2 - September 6</h2>
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    We got more Gibson primers for the creation of the fusion proteins containing TALA and TALB connected to ferritin. The pieces were PCRed out and the Gibson reaction was attempted and subsequently transformed. All of the resulting colonies did not contain our desired part and this may be due to the presence of template vector originally used for the PCRs. Therefore we will attempt to DPN1 treat the DNA in order to chew up the original vector.
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<h2>Week 20: September 9 - September 13</h2>
<h2>Week 20: September 9 - September 13</h2>
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    The western blots for beta-lactamase and the TAL constructs appear to look good, despite the very faint bands seen on SDS-PAGE. Therefore it is possible ferritin is being expressed as well, but is too difficult to see due to background. We may attempt to try to clean up the sample through some crude purification techniques such as treating the sample at 75C, exploiting the stability of ferritin. Alternatively, once we attach the his-tag to our main coil-ferritin construct, we can try to observe ferritin experssion through western blots as well.
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<h2>Week 21: September 16 - September 20</h2>
<h2>Week 21: September 16 - September 20</h2>
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    DNA submission time and a huge rush to plasmid switch everything in addition to participating in <a href="https://2013.igem.org/Team:Calgary/Sandbox/Outreach/Beakerhead">Beakerhead</a> and aGEM.
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<h2>Week 22: September 23 - September 27</h2>
<h2>Week 22: September 23 - September 27</h2>

Latest revision as of 23:51, 22 September 2013

Reporter Journal

Week 1: May 1 - May 3

This week we attended the appropriate safety courses required by our University to work in the lab. Besides that, the undergraduate supervisors presented about the principles of Genetics and Synthetic Biology to the new team members.

Week 2: May 6 - May 10

This week we participated in a general molecular biology workshop to refresh our memory of techniques used in molecular biology.

Week 3: May 13 - May 17

We continued the molecular biology workshop. This week we also divided up into our respective groups for the project and decided research priorities.

Week 4: May 20 - May 24

We examined three problems related to ferritin. Firstly, we investigated protein isolation of ferritin. We are considering the protocols created by Santambrogio et al. (1993), as they have been used by multiple other authors as well. This paper uses precipitation followed by column chromatography, and verification with spectroscopy, PAGE and SDS-PAGE (Levi 1994). Alternatively, we may consider using his-tags for Ni-NTA column purification.

Secondly, we examined the feasibility of using magnetism to manipulate ferritin. Commercial horse spleen ferritin was tested on a magnetic Dynabead rack, and as expected, it did not move, as the core should not be magnetic. We must thus synthesize magnetoferritin wherein the native ferrihydrite core is converted to magnetite--a paramagnetic material which can be attracted to magnetic fields (Jordan et al. 2010, Wong et al. 1998). We were able to attain some general knowledge of magnetism in nano-scale material, including a basic understanding of blocking temperatures, superparamagnetism and magnetic moments, all magnetism-related measurements. But we are ill-equipped to model this system theoretically in terms of calculated forces. We also explore the possibility of alternative magnetic particles, in the case ferritin is too small to exhibit magnetic forces significant enough to move proteins.

Magnetosomes were found to be much larger, but unviable due to the complexity of their creation. The CCMV virus may also be an option, although there is currently little known about it and therefore further research into this topic is required. (Lohsse et al. 2011).

Because we also intend to scaffold proteins to ferritin as in our TALE DNA-binding proteins, we looked into fusions to both C- and N-terminals of ferritin. The N- and C- termini of ferritin subunits are present on the outside and inside of the nanoparticle respectively, and therefore N-terminal fusions are an obvious choice to ensure TALEs are present on the exterior of the nanoparticles (Dorner et al. 1985).

Week 5: May 27 - May 31

While we are unsure of exactly how ferritin will be used in our project, any capacity in which we use it requires isolating recombinant ferritin from E. coli. We investigated which terminus to locate purification tags (eg, His tags) on ferritin subunits. Ingrassia et al. (2006) found that small amino acid additions to the C-terminus of either heavy or light chain ferritin are not deleterious to its function. Thus, we are contemplating fusing proteins to the N-terminal of ferritin as discussed last week, and using the C-terminus for tags to isolate recombinant subunits.

We also contemplated methods for controlling expression in terms of proportions of H and L subunits in completed ferritin. This could influence iron dynamics of completed ferritin. Lee et al. (2002) overcame this issue by fusing the heavy and light chains together to ensure that completed nanoparticles have a 1:1 ratio of each subunit. We are trying to determine pitfalls of this expression strategy. Finally, we investigated methods for validating nanoparticle formation. Namely, we considered fluorescence spectroscopy as tested by Parker et al. (2008), where 410nm output was indicative of iron incorporation as per assembled ferritins.

Apart from using magnetism to manipulate magnetoferritin to isolate pathogenic DNA, we developed a backup approach. Watt et al. (2012) constructed a nanoscale battery where ferritins with two different cores were oxidized and reduced on gold electrodes. We are contemplating using a split TALE capture system to bring ferritin into close association of an electrode. Current could then flow from ferritin into an electrode to indicate binding of pathogenic DNA. Finally, we considered how we might construct a magnetic device to isolate ferritin. Bushart et al. (2006) discussed method for isolating metal chelating magnetoferritin for metal purification. However, the necessary magnetic field strengths, mesh density, or mass of isolated compounds in these systems were not explicit. Thus, we are still uncertain about the feasibility of using magnetism to isolate proteins attached to magnetoferritin.

Week 6: June 3 - June 7

The application of ferritin in our project has changed substantially. Due to uncertainties of using magnetism to isolate proteins attached to ferritin, our team proposes instead to use it as a nanoscale protein scaffold. Our team was inspired by the work of REFERENCE et al. (2011) who used gold nanoparticles bound to ssDNA to detect DNA in a lateral flow strip assay.

We have decided to modify the aforementioned system. We’ll replace gold nanoparticle with ferritin and ssDNA with TALEs targeted to pathogenic E. coli markers. These nanoparticles will bind pathogen DNA via TALEs, be drawn up through a strip via capillary action, and become immobilized with complementary TALEs affixed to other regions on the strip. A reporter marker will also be fused to the recombinant ferritins to allow visualization of the pathogenic DNA.

This system is unique since double stranded sample DNA could be detected without having to first melt the DNA. Cheap prototypes for such a system could be constructed and would be suitable for cost constraints in the beef industry. Moreover, this system is amenable to scale-up for the identification of multiple pathogenic markers on a single lateral flow strip. We are, however, unsure as to what to use as a reporter enzyme.

We also met with two U of C professors in nanoscience to discuss the feasibility of our magnetism idea. Dr. Max Anikovskiy, an instructor from the nanoscience program, allowed us to use a 50 lb. pull force rare earth magnet to manipulate native horse spleen ferritin. However, there were no changes over a three hour period. We also spoke to Dr. Simon Trudel from the nanomagnetism research group. He seemed to think our idea was feasible, but might require optimizing with respect to the solvent system in which the particles are dissolved. From both these meetings, it emerged that modelling the fluid dynamics is beyond our capabilities. Our best bet is to test these ideas experimentally, one step at a time, by first synthesizing and testing magnetoferritin.

MAKE A FIGURE OF LATERAL FLOW STRIP

Week 7: June 10 - June 14

We visited the Cargill Meat Solutions plant and discovered that our system would be most applicable in identifying cattle who are super shedders, which would require our system to be quantitative. One possible approach utilizes a fusion of TAL and a reporter protein, although this system may subtract from quantification due to binding of multiple DNA strands to the nanoparticle.FIGURE?? An alternative approach utilizes a ferritin-TAL to immobilize target DNA, which can then be visualized through a second TAL fused to a reporter enzyme. FIGURE??

One question we currently have is in the construction of the ferritin genes. Lee et al. (2002), and Huh and Kim (2003) have successfully created heavy-light chain ferritin subunit fusions, allowing better control of the subunit ratios. Therefore we intend to use a similar approach as it would halve the number of subunits involved, and in turn halve the number of bound TALs, reducing our concerns about steric hindrance. E-coils will be bound to the N-terminus due to its presence on the outside of the nanoparticle, ensuring exposure to the environment (Luzzago and Cesareni 1989).

Upon further investigation, we found that the creation of Prussian Blue ferritin nanoparticles involve the use of potassium ferrocyanide, a compound that has the potential to evolve hydrogen cyanide. These fears were abated upon contacting members in the nanoscience department, stating the conditions and concentrations involve in our experiment were too low to be of concern.

Week 8: June 17 - June 21

An issue we addressed this week was the assembly of gene constructs to test ferritin in our system. A tentative strategy plan has been proposed. Coordinating this plan with the TALE and linker teams is necessary to ensure compatibility among the many components of this project. Upon receiving commercially-synthesized genes, we will order primers to use the Golden Gate assembly method.

To test whether the synthesis of magnetoferritin is successful, we must first synthesize it using the method proposed in week 4, where the native ferrihydrite core is converted to apoferritin then magnetite. Using a magnet with a relatively strong pull force (about 50 lbs.), we hope to see the magnetoferritin respond in solution.

We must also confirm the applicability of using ferritin as the Prussian blue reporter system. After generating ferritin with a Prussian blue ferrihydrite core, we will manipulate the core type, pH, coloured substrate, and temperature to test the feasibility of this method. If these tests are futile, we may need to develop an enzymatic reporter that will function in parallel with our system. The necessary materials have been obtained for these experiments, and results will follow shortly.

Week 9: June 24 - June 28

In order to use beta-lactamase as a potential reporter system it was necessary to use designed primers to PCR out the gene from the backbone of the pSB1A3 plasmid (it is present here as it conveys ampicillin resistance). Three primers were designed in order to retrieve the beta-lactamase gene just by itself as well as having it with a His-tag in order to aid with protein purification. After the PCR was performed the resulting DNA was run on a gel to confirm the gene size (Figure 2). This PCR appeared to be successful based on size (900-bp and 927-bp for the beta-lactamase and beta-lactamase with His-tag respectively) but after sequencing it was determined one of the primers contained a design error resulting in a truncated gene. The primers will be redesigned in order to successfully achieve the extraction of the beta-lactamase gene from the pSB1A3 plasmid.

Beta-lactamase PCR Extraction

Figure 2. PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. 5 out of the 8 lanes for the beta-lactamase extraction display bands at approximately 900-bp which is expected as the part should be 909-bp. All of the lanes for the extraction that includes the His-tag show bands at that are a similar size compared to the normal beta-lactamse extraction which is expected as the gene is 927-bp in size. Some unexpected amplification is seen for this PCR set. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour.

Week 10: July 1 - July 5

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Week 11: July 8 - July 12

Our team reviewed primers design for our Golden Gate Assembly with emphasis on ensuring proper ligation of our products. This involved matching melting temperatures, ensuring there were no palindromic sequences, and considering the other requirements involved. Primer design is integral to our overall project since we must successfully use Golden Gate Assembly to synthesize our parts. Much of our time has been spent towards this goal.

Also, Ferritin gene sequences have arrived. We have transformed, MiniPrepped and ready as a template for the Golden Gate primers.

Also received this week were the redesigned primers for extracting beta-lactamase from the pSB1A3 plasmid. These primers were used in three combinations to produce the beta-lactamase gene by itself, the beta-lactamase gene with a His-tag at the end and a beta-lactamase gene with a flexible glycine linker (BBa_K157013) fused to the N-terminus of the protein. The gels of these PCRs indicated that the experiment was successful (Figures 6, 7). These products were PCR purified in order to be used for constructions.

Beta-lactamase PCR Extraction Attempt Two

Figure 6. PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. Every lane for the beta-lactamase extraction display bands at approximately 900-bp which is expected as the part should be 909-bp. All of the lanes for the extraction that includes the His-tag show bands at that are a similar size compared to the normal beta-lactamse extraction which is expected as the gene is 927-bp in size. Some unexpected amplification is seen for this PCR set. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour.

Beta-lactamase with Linker PCR Extraction

Figure 7. PCR making use of custom primers to extract Beta-lactamase from the psB1A3 vector. Expected band sizes were seen for all of the extractions at approximately 950-bp. Some unexpected amplification is seen for this PCR. No contamination is observed in the NTCs (no template controls). The gel was 1% agarose and was run at 100 V for an hour

A construction that was attempted this week consisted of placing the beta-lactmase gene with a His-tag behind the promoter BBa_J04500. Also attempted were plasmid switches of the three beta-lactamase genes extracted via PCR. Colonies were seen for all of the transformed ligation mixtures for these constructions. Colony PCR of these transformed colonies only produced potentially viable results J04500 + Beta-lactamase (with His-tag) construct.

Week 12: July 15 - July 19

The primers for golden gate assembly arrived this week and we conducted the PCRs required for our first attempt at making our constructs. The final ligation product was run on a gel and appears promising, showing a 1500bp band, most likely representing our construct. Despite this, transformations have failed and therefore we have to look back at our primers and experimental design.

We now have a more set idea of how we’re going to synthesize magnetoferritin. We will most likely be using a flask with a rubber stopper that will allow inflow and outflow of the nitrogen gas, which will be bubbled into the solution with an air stone. Nitrogen is free to exit a small port in the stopper and reagents can easily be added via injection through the rubber stopper. Safe handling of the thioglycollic acid is paramount, therefore equipment has been ordered (elbow-length gloves, respirator, apron, and something else), and attempts at synthesis will be conducted as soon as we get the equipment.

The beta-lactamase construction attempted last week proved to be unsuccessful however another construction from this week did produce a gene that appeared to be the J04500 + Beta-lactamase with a His-tag part. This construction was sent in for sequencing over the weekend.

Week 13: July 22 - July 26

The sequencing of the J04500 + Beta-lactamase with a His-tag construction from last week revealed that we had successfully completed this part.Mutagenesis primers were designed for this gene as a BsaI cut site is present in the sequence which could interfere with any Golden Gate assembly attempted with this part. Successful mutation of this part was completed and confirmed via gel electrophoresis and sequencing. A preliminary test was also attempted with this part in order to see if the leaky properties of the LacI (BBa_J04500) promoter could successfully produce beta-lactamase at levels large enough to allow the transformed cells to survive on plates containing ampicillin even though this part exists in a chloramphenicol resistant plasmid (pSB1C3). This test successfully displayed that active beta-lactamase was being produced by our cells. Also produced this week was the plasmid switch of the beta-lactamase gene with a His-tag at the C-terminus, the beta-lactamase gene with a glycine linker at the N-terminus.

Week 14: July 29 - August 2

Realizing the time constraints we have for the submission of our parts, we reviewed our Golden Gate assembly experiment to ensure we can submit the parts to the registry. In case this method fails, we also began development of Gibson assembly primers to see if this assembly assembly method cooperates with us.

We began characterization of prussian blue ferritin through kinetics experiments. Our first goal was the construction Michaelis-Menten plot to determine the activity of our peroxidase-like catalyst with the 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS) substrate which ended up looking like this: INSRERT GAPHHHH These experiments then continued on to optimization experiments wherein we determined the optimal pH, temperature, and concentrations of ABTS and H2O2. We intend to repeat these experiments 3,3',5,5'-tetramethylbenzidine so that we could compare the two substrates and determine the most viable one for our final system.

Week 15: August 5 - August 9

Prepared the basic reagents for magnetoferritin synthesis, we attempted to create apoferritin this week. Apoferritin turned out to be very light brown, suggesting some of the iron cores were unloaded. Moved onto magnetoferritin synthesis, but the resulting product contained a lot of particles in it, we fear this may be due to synthesis of magnetite crystals in addition to magnetoferritin.

We did our tested heavy ferritin as ordered from the synthesis company for expression on an SDS-PAGE. The J04500 LacI induced promoter was induced with 0.8mM IPTG for four hours at 0.6OD for the cultures. The protein was either not expressed or was too difficult to distinguish from the background proteins in the cell. Protein trials will be repeated once we assemble construct two in iGEM’s pSB1C3.

Also continued on with the ABTS kinetics experiments. We were able to create graphs showing the effectiveness of our catalyst under varying pH.

GAPHPPHPHPH

Week 16: August 12 - August 16

Finished off the ABTS kinetics experiments for prussian blue ferritin, which involved finding the optimal temperature for the reaction. But the spectrophotometer available to us is limited to 25-45C. This limitation is still within our expected prototype temperature and therefore it is not a big worry. We will then continue on with determining the kinetics for TMB and find out which substrate is better for our system.

Week 17: August 19 - August 23

Due to multiple failures of the plasmid switches of both ferritin and other parts, we conducted tests on multiple aspects of our procedures, including ligase, phosphatase and buffer. None of these parts were determined to be problematic, therefore we attempted higher DNA concentrations on controls, which worked. Therefore we will attempt the plasmid switch of the ferritin parts at some other time.

We also began initial tests with TMB, but realized our stock concentrations were at 1mg/mL. As these results would be incomparable to our ABTS experiments, which were at 10mg/mL, we remade the TMB stock solution to 10mg/mL and redid the experiments.

Week 18: August 26 - August 30

Our first attempts at observing one of our fusion proteins on SDS-PAGE were conducted, although the bands do not appear to contain the protein. We’ve read about a technique that can stain iron, which is essentially the same as the creation of Prussian Blue ferritin. Using this method we could exploit the iron core of ferritin by running a native PAGE and staining the iron core. This would then confirm the presence of our protein, therefore we ran initial tests of this method by running dilutions of the ordered ferritin solution in addition to other things. This method worked extremely well for staining ferritin controls, although the E.coli samples lack the bands, which is problematic as this indicates either there is no ferritin being produced, or this stain isn’t sensitive enough for the amount of ferritin produced. FIGRUERUEURE

On a happier note, our work with gibson assembly has finally produced one of our constructs, the fusion of the heavy and light ferritin chains to an E-coil. Because this method appears to be relatively successful, we intend to order more primers and use Gibson assembly for the construction of other parts as well.

Week 19: September 2 - September 6

We got more Gibson primers for the creation of the fusion proteins containing TALA and TALB connected to ferritin. The pieces were PCRed out and the Gibson reaction was attempted and subsequently transformed. All of the resulting colonies did not contain our desired part and this may be due to the presence of template vector originally used for the PCRs. Therefore we will attempt to DPN1 treat the DNA in order to chew up the original vector.

Week 20: September 9 - September 13

The western blots for beta-lactamase and the TAL constructs appear to look good, despite the very faint bands seen on SDS-PAGE. Therefore it is possible ferritin is being expressed as well, but is too difficult to see due to background. We may attempt to try to clean up the sample through some crude purification techniques such as treating the sample at 75C, exploiting the stability of ferritin. Alternatively, once we attach the his-tag to our main coil-ferritin construct, we can try to observe ferritin experssion through western blots as well.

Week 21: September 16 - September 20

DNA submission time and a huge rush to plasmid switch everything in addition to participating in Beakerhead and aGEM.

Week 22: September 23 - September 27

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Week 23: September 30 - October 4

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