Team:Washington/Plastics

From 2012.igem.org

Revision as of 19:17, 3 October 2012 by Licina (Talk | contribs)

“Plastics: made to last forever, designed to throw away”--5gyres.org

Background

The increasing problem of plastic waste.

Playing an integral role in our modern world, plastics account for over a third of products made today. They have a relatively low cost of production, serve to promote the development of industry, lower the cost of consumer goods, and are easy to produce on a large scale. Plastics, regardless of disposability, compose 10% of the waste generated in the world and an even higher percentage is carelessly thrown into our environment [1]. Plastic pollution discharges debris into the ocean that are ingested by wildlife, often resulting in injury or death [2].


The PUR Problem

A commonly used plastic, Polyurethane (PUR), is used to create a wide range of products including dense solids, rigid insulating foam, and thermoset elastics. Because of its extreme versatility, the world consumption of PUR is continually increasing. According to current market analysis, the global production of PUR is estimated at 27 billion pounds per year and is expected to increase to 36 billion pounds by the year 2016 [3]. The leading method of recycling polyurethane is to mechanically grind the waste and rebind it into carpet cushioning, accounting for about 4% of waste polyurethane [4]. However, due to the high costs of transportation and chemical degradation, most PURs are incinerated to recapture some of the energy used to make them [5].


Current Means of Disposal are Undesirable

Current methods of disposal, like burning is harmful for our environment.

Non-biodegradable plastics are often disposed of through waste incineration as it is the most efficient method of degradation. However, a major issue with this is that the products of plastic burning, which include polychlorinated di-benzo-p-dioxins/furans and carbon dioxide, are known to be carcinogenic [6]. Upon incineration, these gaseous products are released into the atmosphere and have the potential to cause future problems to human health as well as contribute to global warming. An additional concern, plastics constitute large volumes of space as they are habitually disposed of in landfills. It has been shown that plasticizers and plastic additives leak from the these plastics and contaminate aquatic environments [7]. Thus because of the environmental damage that current disposal methods incur, there is a large need for safer methods of plastic degradation.


Engineering Microbes to Degrade PUR

To solve the problem of PUR recycling, we propose a bacteria that is both able to degrade PUR and subsist off of the products of degradation as its sole carbon source. To this end, we propose a two plasmid system. The first plasmid would have two genes. The first gene, polyeurethane esterase, will encode an enzyme that is able to break down the PUR polymer structure into two molecules, one of which, ethylene glycol, can diffuse across the membrane of the bacterium [8]. The second gene, osmotic inducible protein Y (osmY), would encode a protein that is fused to PUR esterase and exports the enzyme through the cell membrane and into the supernatant [9]. The second plasmid would have an operon composed of, glycolaldehyde reductase (fucO) and glycoaldehyde dehydrogenase (aldA), that allow the bacterium to use ethylene glycol as its central metabolite [10]. This system would allow the bacteria to turn the plastics plaguing our landfills into bacterial biomass which would in turn degrade more PUR.

The complete system pathway takes PUR, an undesirable waste product and converts it into food for the bacterium.



Our App: The Turbidostat[Top]

Schematic diagram of our turbidostat. It uses the optical density measurements to modulate how much media is pumped into the culture vessel every minute to maintain a constant cell density.
Recycleapp.png

To characterize and optimize growth of specific parts of our overal polyurethane degradation pathway we developed a homemade software application (App). Our App uniquely controls an assortment of hardware devices easily found online, creating a fully functional turbidostat. A turbidostat is a closed-loop continuous culture device that maintains a desired constant cell density and chemical environment. The constant environment allows for continuous log phase growth and constant selective pressures (in our case polyurethane or ethylene glycol), which enables proper characterization (seen through media input per dilution cycle) and reduces evolutionary trajectory drift [11]. By maintaining constant selective pressures, the rate of evolution is also dramatically improved [11]. By creating this turbidostat App (written in Python), we are able to properly asses and optimize, given enough time, our individual parts as well as the entire polyurethane degrading circuit in a controlled and reliable manner.





Methods [Top]

To assemble the polyurethane esterase, we used 4 IDT gBlocks and Gibsoned them together onto a pGA backbone.

PUR Esterase Assay

Polyurethane esterase degrades polyurethane by cleaving the ester bonds to produce one of a variety of monomers with isocyanate groups on either end and (poly)ethylene glycol. For our circuit, we have chosen to use the esterase estCS2 ([http://partsregistry.org/Part:BBa_K892012 BBa_K892012]). Originally isolated and characterized by Kang et al (Microbial Cell Factories 2011), the sequence of estCS2 is available at [http://www.ncbi.nlm.nih.gov/nuccore/283462288 GenBank (GU256649)]. Since their DNA constructs were unavailable and the authors did not respond to requests, we synthetically constructed the entire 1.7kb estCS2 gene from four 500-base gBlocks provided by IDT using Gibson cloning.


To assemble for activity of polyurethane esterase, cells transformed with the PUR esterase plasmid were grown to saturation, sonicated, then a piece of pre-weighed polyurethane foam was inserted into the culture tube.

To assay esterase activity we made one 50mL TB + kan overnight culture each for cells containing the esterase plasmid and cells without the plasmid. After leaving the cultures overnight, we spun them down to form a pellet. After pouring out the supernatant, we resuspended the cells in enough water for them to be equalized at an arbitrary OD of 1.4 and aliquoted out each of the two cell types 1mL at a time into 3 different eppendorf tubes. We then sonicated the cells at an amplitude of 20 with 1 second pulses on and off for 30 seconds. After sonication we applied the entire 1mL of lysate to preweighed samples of foam with an additional 1 mL of LB. We made 3 replicates of each cell type (untransformed MG1655, transformed MG1655, and no cells) and left the tubes in room temperature overnight.


Exporter Protein OsmY Assay

Since polyurethane is a large polymer, larger than the cell itself, it cannot be imported for degradation and therefore our esterase must be exported. It has been shown in Bolkinsky, Gregory et al that a protein, osmotically inducible protein Y (osmY, [http://partsregistry.org/Part:BBa_K892008 BBa_K892008]), is naturally exported by E. coli [9]. Furthermore this paper shows that osmY can be used as an export tag in E. coli when it is translationally fused to a protein.

Our exporter protein (osmY) is linked to sfGFP through a serine glycine linker.
To test for exportation of osmY into the supernatant, we used our osmY fused to sfGFP and as a control sfGFP fused to mamI in the same translational conformation. These cells were grown up and then they were spun down and the fluorescence of the supernatant was measured.


To assay the exportation system we created a fusion protein. The fusion protein was super folder GFP (sfGFP) fused to osmY([http://partsregistry.org/Part:BBa_K892008 BBa_K892011]), which allows for visual assessment of whether or not osmY is correctly exporting. For the control, sfGFP was fused to mamI, a protein that binds to the cell membrane. To assess whether or not osmY properly exports proteins outside of the cell membrane, the sfGFP-osmY and sfGFP-mamI cells are spun down in a centrifuge at 3000g for 3 minutes. If the cells expressing the osmY construct have fluorescent supernatant while the supernatant of sfGFP-mamI is not fluorescent then it can be concluded that osmY when fused to a protein is properly exported into the culture environment. But if there is no fluorescence in the supernatant or sfGFP-mamI illustrates the same supernatant fluorescence as the osmY construct than it could be concluded that osmY does not export proteins outside of the cell or our designed fusion between sfGFP and osmY disrupts sfGFP/osmY function.


By putting fucO and aldA onto a single plasmids with a single promote, we were able to create an operon that when transcribed and translated allows microbes to utilize ethylene glycol as a sole carbon source [10].

The Turbidosta Assay

The assay we performed was running the turbidostat using media comprised of only M9 salts and 30 mM ethylene glycol. The turbidostat App tracks cell growth by first blanking (setting optical density (OD) to 0) and then measuring and recording OD values after inoculation. Because OD and cell density are both linearly related, OD is a great proxy for cell density measurements. After blanking on pure M9 ethylene glycol media, MG1655 cells that were transformed with fucO ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K892009 BBa_K892009]) and aldA ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K892010 BBa_K892010]), which were grown in TB to log phase and then were washed with PBS 3 times and then added to the culture vessel to an OD of 0.2. This allowed for the cells still in log phase to divide without exceeding the OD threshold of 0.3 (our desired constant cell density). The turbidostat was then left running overnight and culture density and amount of fresh M9 ethylene glycol media added per dilution cycle were checked in the morning.


The next assay ran was to transform MG1655 with a fucO-aldA operon plasmid ([http://partsregistry.org/Part:BBa_K892013 BBa_K892013]). This operon consists of fucO and aldA being on a single plasmid that contains a single promoter. With this present, transformed MG1655 cells would be theoretically more fit in ethylene glycol since the cells would not have to spend energy on two antibiotic resistance genes (although no antibiotics were used in the media, the cells still transcribe and translate the genes). By running the turbidostat in the same way as with the dual transformation experiment, an idea for how well the transformed operon fairs versus the two plasmid transformation could be gained.



Results Summary [Top]

PUR Esterase Assay Results

We ran the PUR esterase assay and we found that the foam we used did not degrade. We quantified this by measuring the weight of the foam pieces to the nearest milligram before and after we ran the assay. We actually ended up leaving the lysate with the foam for three days to improve degradation but this had no effect on the end result. The reason we think the foam was not degraded was because we did not know the full composition of the foam, it could of had other polymers mixed in with the polyurethane that prevented our enzyme from properly degrading it. Further testing will need to be done to properly assay functionality of our PUR esterase.


Exporter Protein OsmY Assay Results

Each histogram depicts the average normalized fluorescence values for cells plus supernatant, cells only, and supernatant only. The image in the center is a visual representation of the presented data.

When running the osmY assay described in the methods section, we saw that sfGFP fused to osmY ([http://partsregistry.org/Part:BBa_K892008 BBa_K892011]) resulted in a high overall amount of fluorescence in the supernatant versus when sfGFP was fused to mamI. Even though there the cells containing the sfGFP-osmY plasmid exhibited a quantifiable amount of fluorescence, the overall fluorescence of the liquid culture is equally distributed between the inside of the cells and the outside (supernatant) where as for the sfGFP-mamI construct almost all of the fluorescence exhibited in the liquid culture was due to sfGFP within the cells. It can be gathered from this data that osmY when fused to a protein will export the protein out into the supernatant.

Turbidostat Assay Results

M9 30 mM ethylene glycol media injected into the culture vessel every minute to maintain the arbitrary optical density of 0.3.
Optical density measurements of E. coloi transformed with fucO pGA3K3 + aldA pGA1C3 within the turbidostat growing on M9 30 mM ethylene glycol media.

Following the turbidostat assay protocol, we used transformed MG1655 with fucO ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K892009 BBa_K892009]) on a medium copy Kanamycin resistant backbone and aldA ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K892010 BBa_K892010]) on a high copy Chloramphenicol resistant backbone and cultured it up in the turbidostat. The turbidostat was operated overnight and the above data illustrates that the transformed MG1655 grew using ethylene glycol as its sole carbon source, which normal untransformed MG1655 can't do. This is the case because the optical density (OD)/cell density rose from an initial arbitrary OD of 0.18 (time of inoculation) to an OD of 0.3, which was maintained throughout the time of the experiment (15 hours). The turbidostat maintained this OD through constantly imputing amounts of new media into the culture vessel based whenever the OD surpassed 0.3, which was quite frequently. Although time constraints did not allow us to transform MG1655 with our fucO-aldA operon and characterize it, it can be seen from the data above that when fucO and aldA genes are individually transformed and over expressed in MG1655 E. coli, E. coli gains the ability to utilize ethylene glycol as its sole carbon source. The average doubling time (based off of a 10mL culture volume and an average dilution rate of 30µL/min) was 333 minutes, slightly faster than the literature value of 360 minutes [10].



Future Directions [Top]

Putting it All together

The parts as they are right now have not been put into one cell strain and tested as a system. The obvious next step would be to test the efficacy of the entire plastic degrading construct against polyurethane. Using the turbidostat, we have the luxury of having an optimized and continual growth environment for our system to mutate towards improved functionality. Better cell strains would be periodically saved and tested in harsher selective conditions until eventually the strain is able to survive and reproduce off of polyurethane as its sole carbon source. We recognize that this may take many iterations to complete but the end product could potentially be a cell that is able to consume plastic much faster and safer than traditional recycling methods.


Trash to Treasure

After stable growth off of plastic is achieved the next step would be to clone in a third plasmid that would produce some valuable commodity. Washington 2011 demonstrated that diesel fuel can be synthesized from central metabolites using their Petrobrick platform. The addition of the Petrobrick to the system would allow plastic waste to be processed by E. coli which would then turn it into biofuels.


Parts Submitted [Top]

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892008 BBa_K892008 osmY]

The coding sequence for osmotically induced protein Y, a protein that when fused to another protein, gets exported out of E. coli cells.

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892009 BBa_K892009 fucO]

The gene fucO, which codes for glycolaldehyde reductase, is one of the genes required for E. coli to utilize ethylene glycol as a food source. The coding sequence is put behind a strong biofab promoter and RBS.

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892010 BBa_K892010 aldA]

The gene aldA, which codes for glycolaldehyde dehydrogenase, is the other gene required for E. coli to utilize ethylene glycol as a food source. The coding sequence is put behind a strong biofab promoter and RBS.

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892011 BBa_K892011 sfGFP-osmY]

A composite part for osmotically induced protein Y fused downstream to sfGFP using a glycine - serine linker regulated by the lacI promoter ([http://partsregistry.org/wiki/index.php?title=Part:BBa_R0011 BBa_R0011]) and the standard Elowitz RBS ([http://partsregistry.org/wiki/index.php?title=Part:BBa_B0034 BBa_B0034]).

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892012 BBa_K892012 PUR Esterase]

An enzyme that breaks down polyurethane plastic behind the control of the lacI promoter ([http://partsregistry.org/wiki/index.php?title=Part:BBa_R0011 BBa_R0011]) and the standard Elowitz RBS ([http://partsregistry.org/wiki/index.php?title=Part:BBa_B0034 BBa_B0034]).

[http://partsregistry.org/wiki/index.php?title=Part:BBa_K892013 BBa_K892013 fucO-aldA]

The combination of BBa_K892009 and BBa_K892010 behind a strong biofab promoter.



Sources [Top]

  1. Barnes, D. K. A., F. Galgani, R. C. Thompson, and M. Barlaz. "Accumulation and Fragmentation of Plastic Debris in Global Environments." Philosophical Transactions of the Royal Society B: Biological Sciences 364.1526 (2009): 1985-998. Print.
  2. Gregory, M. R. "Environmental Implications of Plastic Debris in Marine Settings--entanglement, Ingestion, Smothering, Hangers-on, Hitch-hiking and Alien Invasions." Philosophical Transactions of the Royal Society B: Biological Sciences 364.1526 (2009): 2013-025. Print.
  3. "Global Polyurethane Market to Reach 9.6 Mln Tons by 2015." Plastemart.com. N.p., 30 Aug. 2011. Web.
  4. "Polyurethane Recycling." Polyurethanes. American Chemistry Council, n.d. Web. .
  5. "Frequently Asked Questions on Polyurethanes." Polyurethanes.org. European Diisocyanate and Polyol Producers Association, n.d. Web. .
  6. Takasuga, T., N. Umetsu, T. Makino, K. Tsubota, KS Sajwan, and KS Kumar. "Role of Temperature and Hydrochloric Acid on the Formation of Chlorinated Hydrocarbons and Polycyclic Aromatic Hydrocarbons during Combustion of Paraffin Powder, Polymers, and Newspaper." Archives of Environmental Contamination and Toxicology (2007): 8-21. Print.
  7. Teuten, E. L., J. M. Saquing, D. R. U. Knappe, M. A. Barlaz, S. Jonsson, A. Bjorn, S. J. Rowland, R. C. Thompson, T. S. Galloway, R. Yamashita, D. Ochi, Y. Watanuki, C. Moore, P. H. Viet, T. S. Tana, M. Prudente, R. Boonyatumanond, M. P. Zakaria, K. Akkhavong, Y. Ogata, H. Hirai, S. Iwasa, K. Mizukawa, Y. Hagino, A. Imamura, M. Saha, and H. Takada. "Transport and Release of Chemicals from Plastics to the Environment and to Wildlife." Philosophical Transactions of the Royal Society B: Biological Sciences 364.1526 (2009): 2027-045. Print.
  8. Kang, Chul-Hyung. "A Novel Family VII Esterase with Industrial Potential from Compost Metagenomic Library." Microbial Cell Factories 10.41 (2011): n. pag. Print.
  9. Bokinsky, Gregory, Et. Al. "Synthesis of Three Advanced Biofuels from Ionic Liquid-penetreated Switchgrass Using Engineered Escherichia Coli." Proceedings of the National Academy of Sciences of the United States of America 108.50 (2011): 19949-9954. Print.
  10. Boronat, Albert, Estrella Caballero, and Juan Aguilar. "Experimental Evolution of a Metabolic Pathway for Ethylene Glycol Utilization by Escherichia Coli." Journal of Bacteriology Jan. (1983): 134-39. Web.
  11. E. Toprak, A. Veres, J. B. Michel, R. Chait, D. L. Hartl, R. Kishony, “Evolutionary paths to antibiotic resistance under dynamically sustained drug selection,” Nature Genetics, vol. 44, no. 1, pp. 101-105, Jan. 2012.