UESTC-China
During the time we designed a flow chart for our CO2 utilization system for
application, We were lucky to find our friend, UESTC-China, to work together and
end up building a completely eco-friendly system with negative carbon footprint.
Our project try to figure out another way in carbon utilization as an
contribution of carbon reduction and save energy. However, we face some problem
when we try to apply our Engineering E. coli into industrial scale. Cost
evaluation and carbon footprint are big challenges
When we were designing the whole CO2 utilization system. We were delighted when
we found out someone who will be able to resolve our problems. UESTC-China, an
iGEM team that focus on degrading straw into useful raw materials, which are
glucose, xylose, ferule acid, and lignin. In addition, they aimed to convert
glucose into butanol and hydrogen. As xylose is the main carbon source for our
engineered E. coli, we came up with a collaboration idea by integrating our
system at the downstream of their system. Xylose is one of the side product
produced during straw degradation, it can be extracted and utilized in our
system. Concerning the synthesis of xylose may produce greenhouse gas and
chemicals, we would like to obtain xylose produced via biological method.
Straw was a bio waste in agriculture while it wasn't easy to decompose.
UESTC-China's work successfully solved this problem with synthetic biology.
Through our collaboration, they can not only produce bioenergy, but have
another powerful application in CO2 emission problem. NCKU-Tainan provided them
a valuable application way and helped them design a draft of device. The xylose
source from straw was really important to E. coli co2 utilization system which
changed the positive carbon footprint into negative carbon footprint.
CO2 emission problems is a big issue in the world. The main solution can be
separated into two part, CO2 downstream processing and Alternative Energy. Both
NCKU-Tainan and UESTC-China contribute to this serious issue and our
collaboration could solve both the energy problem and environment problem.
Tec-Monterrey
We have a video meeting with Tec-Monterrey. After introducing our project to
them, they had pointed out some aspects that we need to consider. They remind
us to think about our end product which can make our project more complete.
During the meeting, we came up with the idea to collaborate with each other.
Their project has two part. The main part is E-coding, which use E. coli to
store data. Another part is to sense the pollutant in river of Mexico, which is
the part that we could link our work. We had constructed a pH sensing biobrick
which express fluorescence under low pH condition, they suggest us to
incorporate our pH sensing construct in their pollutant sensing system, making
their system become more complete. Therefore, we shared our plasmid map and
construction protocol with them, which they can be used to construct the
biobrick in the future.
Also, we found out that the new combined sensing system can be applied in our
bioreactor as they aim to sense pollutants such as nitrate, phosphate or heavy
metals. This will be a useful alert system for our bioreactor since the flue
gas may contain pollutants especially heavy metals that are highly toxic to the
E. coli.
Through this collaboration, we not only combined two sensing system, expanding
its application field, but we also found a more complete sensing system for our
device.