Project overview
Methane is a potent greenhouse gas, and is leaked into the atmosphere at different natural and industrial places. A big part of the industrial methane emission is in the agricultural sector in places like
barns1,
Bacteria in the rumen of cows and other cattle produce methane.
or
paddy fields2,3
Bacteria in the soil that produce methane.
(rice fields). Natural methane emission places are for example
wetlands4
land areas saturated with water in which methane producing bacteria reside.
or
gas hydrates5
Gas hydrates are trapped ice-like crystals of gas that are only stable in a specific temperature and pressure range. Found on continental shelves and under permafrost.
To minimize the leakage of methane in these or other places one would want to breakdown methane locally. Or even better, one could convert methane to methanol or biomass so it can be more easily transported and used as a bio-fuel instead of being discarded. The current technology doesn't allow this kind of small scale local breakdown of methane, because this process requires high pressure and very high temperatures to break the strong bonds within one methane molecule.
6 An attractive alternative is bio-conversion of methane.
Methanotrophs
single-cell organisms that metabolise methane.
can naturally breakdown methane and use it as their sole carbon and energy source. Even better, the enzyme
methane monooxygenase (MMO)
link to more info
that these methanotrophs use can breakdown methane at ambient temperatures and pressure.
6-9
Thus if we could understand and use this enzyme it would be possible to develop tools to minimize the methane leakage at many places like barns and gas hydrates. However our knowledge about methanotrophs is limited and culturing them is relatively difficult and slow. That is why we want to implement MMO into Escherichia coli (E. coli) so that it can breakdown methane. Since methanol, the breakdown product of methane, is poisonous, we will also implement the Ribulose-Monophosphate (RuMP)- pathway from Bacillus methanolicus to convert methanol to biomass in three steps. To hold the bacteria we want to design an air-filter that could be used practically anywhere for this purpose. The first part of our project is based on the
iGEM 2014 team from Braunschweig, Germany
Project goal
References
-
US EPA, C. C. D. U.S. Greenhouse Gas Inventory Report: 1990 - 2013.
-
US EPA, C. C. D. Agriculture.
- Bodelier, P. L. E. Sustainability: Bypassing the methane cycle. Nature 523, 534–5 (2015).
- Liikanen, A., Silvennoinen, H. & Karvo, A. Methane and nitrous oxide fluxes in two coastal wetlands in the northeastern Gulf of Bothnia, Baltic Sea. Boreal Environ. Res. 14, 351–368 (2009).
-
US EPA, C. C. D. Methane Emissions.
- Rosenzweig, A. C. Biochemistry: Breaking methane. Nature 518, 309–10 (2015).
- Sirajuddin, S. & Rosenzweig, A. C. Enzymatic Oxidation of Methane. Biochemistry 54, 2283–94 (2015).
- Sazinsky, M. H. & Lippard, S. J. Methane monooxygenase: functionalizing methane at iron and copper. Met. Ions Life Sci. 15, 205–56 (2015).
- Zhang, Y., Xin, J., Chen, L. & Xia, C. The methane monooxygenase intrinsic activity of kinds of methanotrophs. Appl. Biochem. Biotechnol. 157, 431–41 (2009).