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Module 1: Resourceful Waste

Non-recyclable waste is sourced from a recycling centre, placed in a bioreactor with our M.A.P.L.E system which degrades the waste and synthesises the bioplastic P(3HB). Click the tabs to find out more

Overview
Specifications
Design
Modelling
Assembly
Testing & results
Future work

Mixed waste is one of the major challenges facing waste management as the materials cannot be recovered by recycling processes dedicated to individual materials. As a result the many things made of mixed materials and others that end up this way when disposed of are not properly utilised. We wanted to create a way to recover these materials and produce something useful and valuable from them. We have designed this module to leverage the ability for organisms to work together to carry out complex tasks; in this case breaking down a common mixed waste to release a the valuable platform chemical ethylene glycol and turning the remaining material into the bioplastic poly-3-hydroxybutyrate.

The mixed waste we have chosen is produced in recycling centres as a byproduct of the separation of valuable items from commercial and industrial waste. It is currently disposed of by incineration, causing harm to the environment and human health. It also wastes the resources present, many of which are non-renewable. We are upcycling this waste into new commodities.

To do this we will break down the petrochemical polyurethane to recoup the valuable and finite feedstocks which produced it. We have chosen to break down PUR as we want to expand the range of major petrochemical plastics that can be broken down by the parts registry so that novel functions braking down a range of plastics such as this can be pursued with biobricks.

In order to do this we will secrete polyurethane degrading enzymes, often called PUR esterases, which have the ability to break polyurethane down. These genes are found naturally in organisms which must degrade tough substrates, particularly lignin. This makes them useful in breaking down plastics as these too are resistant polymers. We have tested five of these PUR esterases to find the most effective. One of the products of polyurethane breakdown is the toxic compound ethylene glycol and we have modeled the maximum rate of degradation which will still allow E.coli MG1655 to survive and continue to produce esterases as this is significant for whether this technique could be used to produce industrially relevant levels.

Specification

1. The bacteria should survive and grow in mixed waste

In order for the bacteria to produce bioplastic from the mixed waste they first need to be able to use it as a carbon source

2. The bacteria should secrete a functional polyurethane esterase

To recover the resources from polyurethane in the mixed waste, the enzymes should secrete in an active form.

3. Our Bacteria should be able to tolerate mixed waste degradation products, such as Ethylene Glycol

The products of Polyurethane degradation are toxic and so any bacteria growing with them must be able to survive to a concentration which will allow economical production of ethylene glycol. We have chosen a strain of E.coli-MG1655, which is resistant to ethylene glycol toxicity.

4. The bacteria should produce P3HB

5. The bacteria should produce P3HB from the mixed waste

Design

Petrochemical Plastic degradation

It is known from previous research that some lignin degrading microbial enzymes to be so tough that they can even deal with more difficult polymers: plastics. Some previous iGEM teams have exploited this and worked on enzymatic degradation of various kinds of plastic. We would like to build on this work and extend the plastic degradation capabilities of the synthetic biology community by improving PUR degradation in particular as this has not been successfully achieved before. We have identified 5 PUR-esterase enzymes from the literature that are capable of catalyzing the below reaction.

We have synthesised all of the genes in the below table and are testing them for expression in E.coli, secretion, activity and PUR degradetion capabilities. Our ultimate design is to be able to control the relative levels of different enzymes in waste degrading bio-reactor in order to adjust it to the composition of waste. Therefore we designed the expression constructs accordingly. Our models predict the degradation rate of PUR at the bioreactor scale.

BioBrick Designs

enzyme	source organism	biobrick	reference
EstCS2	uncultured unknown bacterium (GU256649.1)	BBa_K1149002	Kang et.al 2011
pueA	Pseudomonas chlororaphis	BBa_K1149003	Stern et al., 2000
pueB	Pseudomonas chlororaphis	BBa_K1149004	[http://www.sciencedirect.com/science/article/pii/S0964830501000427 >Howard et al., 2001]
pudA	Comamonas acidovorans	BBa_K1149005	[http://www.sciencedirect.com/science/article/pii/S0964830598000663>Allen et al. 1999]
pulA	Pseudomonas fluorescens	BBa_K1149006	[http://www.sciencedirect.com/science/article/pii/S0964830598000687 Vega et al., 1999]

Bioplastic Synthesis

Poly-3-hydroxybutyrate(P3HB) is a bioplastic which is naturally produced inside bacteria such as Ralstonia eutropha, where it accumulates as globules inside the cell. In its native bacteria it is produced as an energy store(1) but it is as a plastic that it interests researchers and industrialists.

We have made P3HB in E.coli, transferring three genes, naturally found in Ralstonia eutropha into E.coli MG1655. These encode the three enzymes necessary for P3HB production; polyhydroxyalkanoate synthase(phaC), 3-ketothiolase(phaA) and acetoacetyl coenzyme A reductase(phaB). These are encoded by the phaCAB operon. We have altered the expression of these three genes to maximise the production of P3HB as high yields are required for it to be economically viable.

Secretion

E.coli is commonly used as a chassis in innovative iGEM project that aim to prove the concept and make the case for a novel function in a biologically engineered machine. In our case, we aim to degrade and synthesise plastic and the degradation part of our system needs to be extacellular. There are not only such biotechnological but also many other reasons for the extracellular targeting of a protein: It can be a product with a medical function, like the [http://www.2009.igem.org/Team:METU-Gene/EGF_Transportation EGF hormone in a previous iGEM project] or be important in bioremediation such as in [https://2013.igem.org/Team:Dundee/Project/Mop Dundee Team’s toximop system] and much more. There are many strategies for secretion. On the following page, you can read about these and find out why we chose the pelB tag for all our degradation enzymes and how we improved the ESTCS2 esterase by changing the phoA outer-membrane anchoring tag in the original Biobrick to pelB. Our story will help you to choose a secretion strategy best suited to your project and also give you guidance with the technical details of using it.

Alternative strategies for protein secretion in E.coli:

N terminal secretion-signal peptides are recognised by the sec pathway . The pathway transports to the periplasm and additional mechanism are usually necessary to further export the protein to the extracellular space. An approach for using this pathway is the addition of an N terminal signal peptide to the target protein which can obtain as high as 90% efficiency in secretion to the extracellular space. Such signals are pelB and phoA tags which are available as biobricks. PelB can get cleaved off by pelB peptidase in the periplasm but phoA will anchor your protein to this localisation.

Fusion partners are endogenous proteins that naturally get secreted in E.coli and can be fused to the target protein. Some such proteins were demonstrated to be a powerful carriers of medically relevant human proteins in E.coli. The yebF and ompF proteins exit the cell via the sec pathway and use additional mechanism for leaving the periplasm where they interact with outer-membrane porins for extracellular secretion. The osmY is available as a Biobrick and we have submitted ompF this year.

The porin proteins such as ompF and ompA, can be used as fusion partners too and anchor proteins to the outer surface of E.coli.

ABC transporters use ATP for transport of specific proteins across the bacterial membrane. The ABC transporter of Erwinia chrysanthemi can be expressed in E.coli and export proteins that contain the LARD1 domain as a C terminal fusion. The system is biobricked in two separate plasmids (transporter, LARD1) with different antibiotic resistance and it is important to use both at the same time.

The [http://parts.igem.org/Protein_domains/Localization page] in the registry that lists localisation tags] is incomplete and contains eukaryotic and prokaryotic localisation signals mixed together. We have therefore put together the tables below for you to help choose an E.coli secretion strategy that is suitable for your project.

Extracellular Secretion in E.coli:

	Description	Biobrick	Team
pelB	type II secretion signal peptide, cleaved off in periplasm	BBa_K208004 BBa_K1149022 BBa_K208004 BBa_J32015	lots eg. Imperial 2013
yebF	large fusion-protein, Sec-pathway and additional mechanism	BBa_K1149001	Imperial 2013
osmY	large fusion-protein, Sec-pathway and additional mechanism	BBa_K892008	Washington 2012
LARD 1	Lipase ABC transporter recognition domain	BBa_K258001	METU-GEne 2009

Outer Membrane Anchors and Periplasmic Expression in E.coli:

	Description	Biobrick	Team
ompF	porin protein that can be fused to a protein, anchors to outer membrane	BBa_K864204	Uppsala 2012
ompA	porin protein that can be fused to a protein, anchors to outer membrane	BBa_K103006	Wasraw 2008
INP	short domain,anchors in periplasm	BBa_K523013 (INP-YFP) BBa_K632002 (INP-Silicatein)	Minnesota 2011 Edinburgh 2011
torA	anchors in periplasm		Dundee 2013
phoA	tag for sec pathway, anchors to OM	BBa_K808028	Darmstadt 2011

Our choice is to use the pelB secretion tag as it has been demonstrated to work in many cases with sometimes as high as 90% transport efficiency. The pelB has been used in iGEM project for many years and is part of 50+ constructs. The UC-Davis team last year used it to secrete LC-Cutinase, a PET plastic degrading enzyme ( BBa_K936013) successfully which is somewhat similar to our plastic degradation enzymes.

Assembly methods and toolkit:

An advantage of the pelB is that it is relatively short (only 66 BP) and we could get our gene synthesised with the tag. A problem with standard biobrick assembly is that the scar site contains a STOP codon and therefore [http://parts.igem.org/Protein_domains alternative strategies are needed]. One of the ways around this is to use Infusion/Gibson assembly which we also had a go with and you can find instructions under our protocols section. We have constructed a biobrick where LARD1 is after a constitutive promoter and RBS in order to facilitate quicker cloning with less assembly steps, [http://parts.igem.org/Part:BBa_K1149021 BBa_K1149021].

Unfortunately, the pelB tag did not prove to be the best strategy for secreting our degradation enzymes in the MG1655 strain. Therefore, we are changing the strategy to use osmY.

References

Economou A. Following the leader: bacterial protein export through the Sec pathway. Trends in microbiology 1999;7(8) 315-320.
Thanassi DG, Hultgren SJ. Multiple pathways allow protein secretion across the bacterial outer membrane. Current opinion in cell biology 2000;12(4) 420-430.
Sletta H, Tondervik A, Hakvag S, Aune TEV, Nedal A, Aune R, et al. The presence of N-terminal secretion signal sequences leads to strong stimulation of the total expression levels of three tested medically important proteins during high-cell-density cultivations of Escherichia coli. Applied and Environmental Microbiology 2007;73(3) 906-912.
Qian Z, Xia X, Choi JH, Lee SY. Proteome-based identification of fusion partner for high-level extracellular production of recombinant proteins in Escherichia coli. Biotechnology and bioengineering 2008;101(3) 587-601.
Prehna G, Zhang G, Gong X, Duszyk M, Okon M, McIntosh LP, et al. A Protein Export Pathway Involving Escherichia coil Porins. Structure 2012;20(7) 1154-1166.
Binet R, Letoffe S, Ghigo JM, Delepelaire P, Wandersman C. Protein secretion by Gram-negative bacterial ABC exporters - A review. Gene 1997;192(1) 7-11.
Chung CW, You J, Kim K, Moon Y, Kim H, Ahn JH. Export of recombinant proteins in Escherichia coli using ABC transporter with an attached lipase ABC transporter recognition domain (LARD). Microbial Cell Factories 2009;8 11.
Francetic O, Pugsley AP. Towards the identification of type II secretion signals in a nonacylated variant of pullulanase from Klebsiella oxytoca. Journal of Bacteriology 2005;187(20) 7045-7055.
Fu LL, Xu ZR, Li WF, Shuai JB, Lu P, hu CXH. Protein secretion pathways in Bacillus subtilis: Implication for optimization of heterologous protein secretion. Biotechnology Advances 2007;25(1) 1-12.
Cho HY, Yukawa H, Inui M, Doi RH, Wong SL. Production of minicellulosomes from Clostridium cellulovorans in Bacillus subtilis WB800. Applied and Environmental Microbiology 2004;70(9) 5704-5707.
Zhang XZ, Cui ZL, Hong Q, Li SP. High-level expression and secretion of methyl parathion hydrolase in Bacillus subtilis WB800. Applied and Environmental Microbiology 2005;71(7) 4101-4103.

Tolerance to waste

We chose the MG1655 E.coli strain as chassis because it constitutively expresses genes that make it resistant to the potentially toxic molecule. The [http://parts.igem.org/Part:BBa_K892010 AldA] and [http://parts.igem.org/Part:BBa_K892009 FucO] genes have an important role in decreasing the toxic effects of Ethylene-glycol by converting it into Glycolaldehyde which is a link to the cell`s central metabloism. We have received these genes from the registry and future work could be to express these in Bacillus or cellulose degrading organisms to make them tolerant as well.

PHB synthesis Design

We will first use the phaCAB biobrick [http://parts.igem.org/Part:BBa_K934001 BBa_K934001] to produce P3HB. Our aim is the industrial production of P3HB and this require high yields to be economically viable. The results from the metabolic model suggest that to do this the amount of phaB should be increased. To do this we designed constructs with stronger promoters to upregulate the expression of the operon.

The operon was original under the native promoter from Ralstonia eutropha. We designed two promoters to increase transcription. The first uses the constitutive promoter [http://parts.igem.org/Part:BBa_J23104 J23104]. The second was designed as a hybrid promoter incorporating BBa_J23104 and the original promoter due to recent results of high expression from a hybrid promoter[http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0056321]. https://static.igem.org/mediawiki/parts/6/60/PhaCAB_all_kinfds_of_parts.jpg

Safety

Bacteria strains

We used E. coli K-12 strains MG1655, NEB 10 beta, NEB 5 alpha and TOP10 (similar to E. coli K-12 DH 10 beta that fall under Risk Group 1 for the experiments, but eventually only MG1655 strain will be used in the bioreactors. This strain rarely survives outside laboratories, although minor symptoms may show if infected. Meanwhile, the parts we designed are specialised for degrading PUR and they should not harm human health.

Chemical reagents

Some of the reagents we used were slightly toxic to human. In order to reduce the risks of using toxic reagents, we always wear gloves and labcoats. For some toxic reagents, we performed in fume cupboard. Click on the reagents to see the MSDS.

1. [http://www.sigmaaldrich.com/MSDS/MSDS/DisplayMSDSPage.do?country=GB&language=en&productNumber=W222305&brand=ALDRICH&PageToGoToURL=http%3A%2F%2Fwww.sigmaaldrich.com%2Fcatalog%2Fproduct%2Faldrich%2Fw222305%3Flang%3Den Tributyrin]

2. [http://www.sigmaaldrich.com/MSDS/MSDS/DisplayMSDSPage.do?country=GB&language=en&productNumber=458392&brand=ALDRICH&PageToGoToURL=http%3A%2F%2Fwww.sigmaaldrich.com%2Fcatalog%2Fproduct%2Faldrich%2F458392%3Flang%3Den Poly(diethylene glycol adipate)].

3. [http://www.sigmaaldrich.com/MSDS/MSDS/DisplayMSDSPage.do?country=GB&language=en&productNumber=19123&brand=SIGMA&PageToGoToURL=http%3A%2F%2Fwww.sigmaaldrich.com%2Fcatalog%2Fproduct%2Fsigma%2F19123%3Flang%3Den Nile red].

4. [http://www.sigmaaldrich.com/MSDS/MSDS/PleaseWaitMSDSPage.do?language=&country=GB&brand=SIGMA&productNumber=A3256&PageToGoToURL=http://www.sigmaaldrich.com/catalog/product/sigma/a3256?lang=en&region=GB Arabinose].

5. [http://www.sigmaaldrich.com/MSDS/MSDS/DisplayMSDSPage.do?country=GB&language=en&productNumber=N9876&brand=SIGMA&PageToGoToURL=http%3A%2F%2Fwww.sigmaaldrich.com%2Fcatalog%2Fproduct%2Fsigma%2Fn9876%3Flang%3Den 4-Nitrophenyl butyrate].

6. [http://www.sigmaaldrich.com/MSDS/MSDS/DisplayMSDSPage.do?country=GB&language=en&productNumber=N8130&brand=SIGMA&PageToGoToURL=http%3A%2F%2Fwww.sigmaaldrich.com%2Fcatalog%2Fproduct%2Fsigma%2Fn8130%3Flang%3Den 4-Nitrophenyl acetate].

Bioreactor safety

We have come up with a few strategies to prevent release of our bacteria into the environment. Firstly, the bioreactor containing bacteria will have a kill switch that kills bacteria if the bioreactor is opened when operating. We also lyse the cells at the end of reactions to harvest our product P3HB, ensuring that no living bacteria escape the bioreactors.

1 P(3HB) synthesis

This section is about modelling the plastic-synthesising E.coli developed in our project. The plastic that this module synthesises is the bioplastic poly-3-hydroxybutyrate, also known as P(3HB). The content below shows the process of building, designing and optimisation of the model. Also, the considerations, assumptions and limitations will be discussed.

1.1 Specifications for the model

Input = monomer (3HB)
Output = polymer (P(3HB))

1.2 Deterministic model

The model was built and simulated in Simbiology, a Matlab package designed for modelling biological systems. In our model we have a compartment (labelled "E. coli_1") that represents our engineered cell. The compartment contains the reactions and species that interact with the polymer synthesis pathway.

The pathways on the right half of the cell are genetic expressions of the 3 enzymes involved in the plastic synthesis pathway. The pathways on the left represent the actual P(3HB) production pathway.

1.3 Ordinary Differential Equations

Genetic regulations and expressions

BDH2 (3-hydroxybutyrate dehydrogenase)

Schematic of the gene expression of BDH2 as seen in the model diagram

PhaB (Acetoacetyl-CoA reductase)and PhaC (P(3HB) synthase)

Schematic of the gene expression of PhaB and PhaC as seen in the model diagram

Values, sources and assumptions

Parameter	Description	Value	Units	Sources	Assumptions
β	maximum rate of transcription	0.032	mM/min	Please see derivation 1 below.	Please see derivation 1 below.
n	Hill coefficient	2.0	dimensionless	[http://parts.igem.org/Part:pSB1C3?title=Part:pSB1C3]	Rounded to 2.0 from 2.26 as Simbiology wouldn't allow a non-integer value for such parameter.
K	Activation coefficient	0.0031	mM	[http://parts.igem.org/Part:BBa_K206000:Characterization]	Taking the "switch point" as the activation coefficient
d_mRNA	mRNA degradation rate	0.10	1/min	[http://www.ncbi.nlm.nih.gov/pmc/articles/PMC420366/pdf/07X.pdf]	Taking the value of mRNA half-life in E.coli strain MG1655 as 6.8min. rate = ln2/half-life = ln2/6.8 = 0.10
d_protein	Protein degradation rate	0.050	1/min	[http://jb.asm.org/content/189/23/8746.full]	There is no active degradation pathway and that dilution is the dominant way by which the protein level decreases in a cell. Rate = 1/doubling time, where doubling time = 20min. Assuming steady-state growth in LB broth as presented in paper.
k₂	Protein production rate (BDH2)	4.7	1/min	Please see derivation 2 below.	Please see derivation 2 below.
k₃	Protein production rate (PhaCB)	0.58	mM/min	Please see derivation 3 below.	Please see derivation 3 below.
[Arabinose]	Concentration of arabinose	Initial: 0.008	mM
[mRNA]	Concentration of mRNA	-	mM	-	-
[BDH2]	Concentration of BDH2	-	mM	-	-
[PhaB]	Concentration of PhaB	-	mM	-	-
[PhaC]	Concentration of PhaB	-	mM	-	-

Derivations

1.Derivation of the maximal expression rate,β

Average molecular weight (Mw) of a base pair = 660g/mol[http://www.geneinfinity.org/sp/sp_dnaprop.html][http://www.lifetechnologies.com/uk/en/home/references/ambion-tech-support/rna-tools-and-calculators/dna-and-rna-molecular-weights-and-conversions.html]
Average mass of a base pair = 660g/mol x 1.66x10^-24 = 1.1x10^-21g
Volume of an E.coli cell = 1µm³[http://kirschner.med.harvard.edu/files/bionumbers/fundamentalBioNumbersHandout.pdf] = 1x10^-15L
- ∴Mass concentration =
- ∴Molar concentration of 1 base pair in the volume of E.coli = = 1.66x10^-6 mM
BioBrick assembly plasmid pSB1C3 is a high copy number plasmid (100-300 copies per cell)[http://parts.igem.org/Part:pSB1C3?title=Part:pSB1C3]
- assume 200 copies per cell
∴ concentration of the gene per cell = N x 200 x 1.66x10^-6mM, where N = number of base pairs
- ∴ concentration of the gene BDH2 (N = 768) in the volume of an E.coli cell is = 0.25mM
Transcription rate in E.coli = 80bp/s[http://kirschner.med.harvard.edu/files/bionumbers/fundamentalBioNumbersHandout.pdf] = 80 x 1.66x10^-6mM/s = 80 x 1.66x10^-6 x 60mM/min = 7.97x10^-3mM/min
∴ Rate of mRNA_BDH2 production under the control of pBAD = 7.97x10^-3 ÷ 0.25 = 0.032/min

2.Protein production rate of BDH2, k₂

Average molecular weight(Mw) of an amino acid(aa)= 110g/mol[http://www.genscript.com/conversion.html][http://www.promega.com/~/media/Files/Resources/Technical%20References/Amino%20Acid%20Abbreviations%20and%20Molecular%20Weights.pdf]
Average mass of an amino acid = 110g/mol x 1.66x10^-24=1.83x10^-22g/L
- ∴Mass concentration of one aa in the volume of an E.coli = = 1.83x10^-6g/L
- ∴Molar concentration of one aa = = 1.66x10^-5mM
Translation rate = 20aa/s = (20 x 1.66x10^-5 x 60)mM/min = 0.020mM/min
BDH2 comprises of 256aa[http://www.uniprot.org/uniprot/Q2PEN2&format=html]
- ∴concentration of BDH2's aa in the volume of an E.coli = 1.66x10^-5mM x 256 = 4.25x10^-3mM
∴ Rate of protein production = 0.020 ÷ 4.25x10^-3 = 4.7/min

3.Protein production rate for PhaB and PhaC, k₃

Relative promoter strengths: J23104 = 1.3RPU, J23101 = 1.0RPU.
- ∴ 104 is 1.3x stronger than 101.
In absolute units: take GFP synthesis rate (molecules per min per cell) and approximate that as a generic protein synthesis rate for the promoter.
- GFP synthesis rate of 101 = 2232 molecules per min per cell.
- ∴ GFP synthesis rate of 104 = 1.3 x 2232 = 2902 molecules per min per cell
Assume 1 molecule in an E.coli cell gives a concentration of 1nM.
- ∴ GFP synthesis rate of 104 = 2902 x 1nM = 2.9x10^-6nM/min per cell
Plasmid copy number assumed as 200 (as in derivation 1)
- ∴ GFP synthesis rate of 104 in our E.coli = 200 x 2.9x10^-6 = 0.00058nM/min = 0.58mM/min