Team:Aalto-Helsinki/Results
Microbially produced propane holds enormous promise as a potential replacement of portable fossil fuels, but the propane yields with current biological pathways are low. The pathway is complex, and to help concentrate engineering efforts on its critical parts, better quantitative understanding of the pathway is required. Our goals were to build a mathematical model of the pathway to better understand it and create biobricks of the propane pathway to help future teams and researchers to continue improving it.
Built a model of the pathway based on known kinetic properties of the enzymes
Identified major bottlenecks of the propane pathway using our model
Improved our experimental plans according to the modeling results by changing one enzyme to a better homolog and expressing the rate-limiting enzyme from the highest copy number backbone used
Found that propane output was sensitive to NADPH/NADH, suggesting their efficient regeneration might be a limiting factor
Submitted a BioBrick containing three crucial enzymes of the propane pathway
Successfully assembled an insert containing the rest of the pathways components, BUT WERE UNABLE TO… [how do I express this? Petra, Anna?]
Industrial biopropane production would most likely occur as a continuously operated process, as it is economically more feasible in large scale production.T o take the first step towards industrial scale production we wanted to try continuous production of propane using a E. coli strain provided to us by Pauli Kallio from the University of Turku.
Successful batch production to prepare analytical equipment for continuous production
First report ever worldwide of successful microbial production of propane in continuous production
145 hour continuous production experiment in a 500 ml chemostat
Propane yield 22,7 µg/L in reactor gas phase
Well over a 100 million tonnes of cellulosic waste is left unused each year in the European Union alone. To elevate the microbially produced propane to a 2nd generation biofuel and avoid interfering with food production, we wanted to incorporate cellulose hydrolysis into the same bacteria that produces the propane.
Looked into modeling cellulose breakdown, but found that there was not enough information to model the breakdown sufficiently well to get any practical benefit from the model.
What point did we reach in the lab with cellulose?
Amphiphilic proteins are synthetic proteins consisting of a hydrophilic and a hydrophobic domain that have been shown to spontaneously form micellar and vesicular structures. We were interested whether these structures could be used as scaffolds to have subsequent enzymes of the propane pathway in close proximity. We wanted to model whether fusing enzymes to the proteins would disrupt micelle formation and whether our idea could enhance propane output.
Built a stochastic synergy model in Python, simulating enzyme function in cases where two subsequent enzymes stay in close proximity to each other as opposed to moving around independently in a cell
The synergy model predicts a 200-400 % increase in product output if enzymes stay in close proximity to each other
Constructed a geometrical micelle model based on the sizes and structures of the micelle-forming proteins, indicating that it is indeed possible for micellar structures to form even as enzymes are fused to them
Submitted a BioBrick encoding the amphiphilic protein to the registry
Due to time restraints, we were unable to experimentally validate the idea by fusing either two subsequent enzymes of the propane pathway or components of the violacein pathway to the amphiphilic proteins
To validate our amphiphilic brick, we needed a GFP that could be fused to the amino-terminal end of the protein. There was no such brick available on the registry. We wanted to create a GFP BioBrick that could be fused to the N-terminal end of any protein using BioBrick methods.
Submitted a BioBrick encoding GFP with an extra nucleotide prior to the suffix, ensuring that it can be fused to the N-terminal end of a protein using BioBrick assembly methods while maintaining the reading frame
Collaborated with team HS Slovenia to validate the brick
Mathematical modeling is a key component of synthetic biology and also played a central role in our project. Collaboration between modelers and biologists can however be challenging, something we also noticed in our project. We wanted to study how iGEM teams tackle these challenges and are able to integrate modeling to their experimentation.
Created a questionnaire for iGEM teams on collaboration between modeling and experimentation, and studied 2014 teams and professional synthetic biology groups to find out what educational backgrounds team members are coming from
Biggest issues in collaboration between modelers and experimentalists are: lack of knowledge of the other field, lack of common terminology and differences in ways of thinking
Both modelers and biologists need to understand the basics of the other field to be able to effectively collaborate.
Having experimentalists and modelers work close together is beneficial. One approach generally found successful is to have some biologists get involved in modeling to help ensure models are useful for the project and connected to reality.
Regular team meetings for presenting and discussing progress and issues of every field take time, but ensure all team members stay informed and can voice their insights.
Students with a mathematical background are underrepresented in iGEM teams as compared to professional synthetic biology groups.
On the other hand, iGEM teams have relatively many biotechnology students, who often stand seem to act as mediators between the modeling and experimentation.
Finding new collaboration partners in iGEM is not easy, as finding information about different teams projects is time-consuming and often difficult. On the other hand, communication with other teams as well as internal team communication can be difficult due to a multitude of platforms used, often cluttered with non-iGEM content. We wanted to do something to these issues to make iGEM even better.
Worked with Stockholm iGEM team on HumHub, a collaboration platform for iGEM teams, and collaboratively wrote a report on it with them
Created a questionnaire on how teams found their collaboration partners and how they’re keeping in touch with them
Found that 22 out of the 23 teams that answered wished for better means to find collaboration partners with
Built Collab Seeker, a lightweight collaboration search tool, which helps find relevant collaboration partners using keywords and provides their contact information
To read our thoughts on future prospects and on how to carry on from where we left, please see our Future page.
Is there anything in the text below that needs to be included in the text above?Modeling is an important part of synthetic biology. With good models, one can gain insight of the biological phenomena before doing anything in the lab. Understanding the biological system allows us to make better decisions as we modify the system for our purposes. We succeeded in building models that helped our project, even though the cellulose pathway remained a mystery for the modeling team.
We determined the bottlenecks of our reaction, FadB2 being the worst. This caused the lab team to change it to Hbd. After FadB2 the worst bottlenecks are ADO, CAR and Hdb. This knowledge affected our decisions on which backbone we should put which construct. Our pathway is also very sensitive to NADPH and NADH concentrations. See more from our page of modeling propane pathway
We didn't get any meaningful results from our (nonexistent) cellulose model. Check the cellulose page to read more about the degradation pathway and what thoughts our modeling team had.
We determined that it is geometrically possible to form the micelles. We also determined that it would be beneficial to have Car and Ado close together instead of the traditional way of them floating independently in the cell.
This is a link to our lab results page!