Team:BV CAPS Kansas/Project/Notebook
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BV CAPS iGEM Tweets
Notebook
Follow our process!
June 13Dylan, Corinne, and Muriel met with a law professor from UMKC that specializes in biological and chemical patents. We talked about the differences between a patent, copyright, and open source. Just in case we make it big, we know how to protect and share our work!
June 6
Mr. Kessler, Corinne, and Amy all traveled down to Dr. Fenton’s lab to talk about our iGEM project. We learned more about plasmids, restriction sites and more! We are working on creating specific primers for our DNA site directed mutagenesis! It is tedious work and it is the longest primer Qingling has created. We looked over the sequence for pyruvate kinase many times to be exact. We may be getting closer to having a part for the registry!
June 5
Using the tinker cell software for creating the metabolic pathways from CO2 to alkanes, Mason is almost finished! Mason, Corinne, Amy and Austin all chipped in to help with the wiki too, and we are making additions to meet the wiki requirements. It is turning out well, thanks to Austin!
June 3
Even though it is summer time now, we still go to CAPS to talk about iGEM material! We are dedicated students! Today Austin, Corinne, Amy, Mason, and Alec debated between the two different routes for producing a part! Which option should we take? With the assistant of Mr. Kessler, Mr. Whalen, and Mrs. Tuel, we can decide which option to take!
May 30
Our last day of school! Instead of taking an hour long exam, Mason, Corinne, Alec, Muriel, and Amy learned about metabolic pathways! We also began our discussion of primer design to make a biobrick! It is hard to create a primer under certain circumstances, but Corinne has an idea!
May 29
Who knew that making an abstract can be challenging? With the help of Mr. Kessler, Dylan, Muriel, Mason, Corinne, and Amy are trying to edit and correct our information without any distractions. It is a struggle. It is also a tedious task for wording things. Thanks to the iGEM Headquarters, they tweeted us an important requirement for the abstract. Good thing Amy created a twitter account! We found out that the abstract has a limit of 150 words… oops! Onto more editing for the deadline!
May 23
Still in the process of the 3A Assembly, but we are learning many new lab techniques and machines. We used the incubator and the nanodrop machine again! The transformation process takes a long time, literally a full day just ask Alec! While waiting we talked about how complex plasmids are. Also we took our first group picture with all of us, Corinne, Dylan, Muriel, Alec, Austin, Amy and Dylan! For the wiki a few of us wrote each other’s biography. Later, Alec plated the 3A Assembly transformation and controls. A fun fact we learned was synechocystis cyanobacteria was the first photosynthetic autotroph to have its entire genome sequenced!
May 22
Mr. Kessler mailed off our news team members and mentors consent forms. It feels like iGEM is becoming the real deal! We can't wait for what iGEM has in stores for us! During our second meeting today, Corinne, Dylan, Muriel, Alec, Austin, Amy and Dylan discussed what happens when the gene of interest has a standard cut site contained within the coding sequence. Muriel is explaining this concept to the group, this time we have a full team!
May 21
Instead of working on iGEM or the 3A Assembly, Muriel, Alec, Amy, and Mason are privileged to listen to Dr. Barney Graham's work about a vaccine for respiratory syncytial virus fusion! We are fortunate to have these amazing connections.
May 17
Today was our first iGEM team meeting! Even though we were missing a Corinne and Dylan, everyone else including Austin and Muriel discussed about the 3A Assembly and its purpose. One step closer!
May 8
Patience is key. We are moving on to the next step of this procedure. Alec, Amy, and Mason are making seed stocks right now! Meanwhile, Muriel has been helping Dylan with our poster. They grew up a nice batch of E. coli with the broad host range plasmid inside to be ready for the next step, plasmid extraction. Since normal, kit-based extractions do not work for this large of a plasmid; we have to follow a longer protocol from the designers of the plasmid. This protocol requires a particularly dangerous chemical, phenol. We have reached out to Dr. Fenton out of KU Medical Center because we do not stock phenol. Another challenge that arose with the gene itself is that the coding sequence contains a standard restriction site.
May 3
Today Alec, Amy, and Mason checked our work. We used this special tool called the nanodrop machine which calculates the purity of a substance. Thank you Mr. Whalen for introducing this to us! Mason and Alec put a tiny drop of our plasmid onto this machine and found out that it is ultra-pure! What a great feeling!
May 2
Continuing the long and complicated procedure, today Alec, Amy, and Mason started our first 3A Assembly plasmid mini prep! During the process we used our new and expensive micropipettes to re-suspend our cell pellets! Enjoy doing wet labs in class!
May 1
Arrived in the mailbox is the 3A Assembly package from iGEM! At CAPS today Alec, Amy, and Mason opened the box and started reading the directions of the procedure! We grew up cell cultures today by using an inoculating loop to pick up a colony from our agar plate and into the LB broth.
April 26
We have been preparing to transform the cells. This week Muriel made the components of STET solution that will extract the plasmid from the cell. The most challenging component of this solution is making EDTA which requires several days to go in solution with the help of sodium hydroxide, a strong base. One thing that we’ve learned is to see how much time is required for the lab before you start it. Dylan and Muriel have also been teaching the other class and soliciting the help from previous students.
April 20
Meanwhile, Muriel have been in contact with a researcher in Hawaii that helped develop the broad host range plasmid and other parts for cyanobacteria that may be of interest to our project. He warned that this plasmid was difficult to work with and required non-standard protocol. Nevertheless, it’s all we have so far that is cheap and easily accessible.
April 15
We located the plasmid shuffling vector from the 2008 Hawaii iGEM team and we have it with the 2012 distribution kit.
April 8
This week we developed iGEM project ideas. At first, our iGEM project was to use properties of extremophiles, specifically halobacteria, to make the microbes more suitable to biofuel reactors. After seeking local professionals in the field, we finally met with Dr. Fenton from KU Med to talk about our iGEM project. He guided us away from biofuels because there are so many variables that need to be considered and the best conversions do not match the efficiency of normal gasoline. Instead, he directed us to pursue a project that dealt with the overexpression of a protein. After doing some preliminary research on the production of phenylalanine, we realized that that metabolic pathway is more complex than we thought. We chose to up-regulate the pyruvate kinase gene because of its production of fatty acids and their application in biofuels.
March 25
Since the project thesis for iGEM is due next week, Muriel organized a brainstorming meeting. Our project will be more competitive if we build on another team’s project and have at least some experimental data instead of choosing a more ambitious project. However, the project should be scalable so the next year’s team can continue. So far, making microbes survive in saline and extreme temperature environments is our best option. Because of its application with biofuels, we can have an elaborate community outreach program with energy conservation and environmental issues. Although it is not the most challenging project, it can be expanded on with by adding other environmental controls. One of the problems with this, and other projects, is the time limitations. We need to have our data by the end of May so that we can analyze, update the wiki, and make our poster.