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− | + | Design | |
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− | + | <p> <b> Click on the icons in the timeline</b>, and find out about all the insights we gained from our stakeholders and how the dialogues shaped our project. </p> | |
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<p>We could make our cells secrete the cellulases and have them float around in the medium, but the closer the enzymes are in vicinity of each other, the more efficiently they cooperate to degrade cellulose. We also <a href="https://2018.igem.org/Team:Groningen/Model/Stochastic_Modeling" target="_blank">modeled</a> these interactions. Additionally, our cells need to use the freed glucose, thus the closer the enzymes are to the cell, the faster the glucose is taken up and the subsequent styrene synthesis takes place. To achieve this we make use of a mini-cellulosome complex. A cellulosome is a high molecular structure used by cellulose degrading microorganisms in nature to make the hydrolysis of cellulose efficient enough for them to survive on it. As heterologously expressing the entire complex is a daunting task that has never been accomplished before, we use only a subset of the enzymes contained in the natural cellulosome. In our mini-cellulosome three enzymes are bound next to each other on a scaffold that is in turn attached to the cell wall of our yeast. The enzymes are fused to a dockerin by which they are connected to the scaffold via cohesin domains. The scaffold is fused to the mating receptor AGA2, which binds to AGA1 on the cell wall. In this manner, we create both enzyme-enzyme and cellulosome-yeast proximity. The cellulosome-yeast proximity is so effective no reducing sugars can be detected when it degrades cellulose (C). As such there are almost no free sugars for competing organisms, potentially removing the need to sterilize the feedstock.</p> | <p>We could make our cells secrete the cellulases and have them float around in the medium, but the closer the enzymes are in vicinity of each other, the more efficiently they cooperate to degrade cellulose. We also <a href="https://2018.igem.org/Team:Groningen/Model/Stochastic_Modeling" target="_blank">modeled</a> these interactions. Additionally, our cells need to use the freed glucose, thus the closer the enzymes are to the cell, the faster the glucose is taken up and the subsequent styrene synthesis takes place. To achieve this we make use of a mini-cellulosome complex. A cellulosome is a high molecular structure used by cellulose degrading microorganisms in nature to make the hydrolysis of cellulose efficient enough for them to survive on it. As heterologously expressing the entire complex is a daunting task that has never been accomplished before, we use only a subset of the enzymes contained in the natural cellulosome. In our mini-cellulosome three enzymes are bound next to each other on a scaffold that is in turn attached to the cell wall of our yeast. The enzymes are fused to a dockerin by which they are connected to the scaffold via cohesin domains. The scaffold is fused to the mating receptor AGA2, which binds to AGA1 on the cell wall. In this manner, we create both enzyme-enzyme and cellulosome-yeast proximity. The cellulosome-yeast proximity is so effective no reducing sugars can be detected when it degrades cellulose (C). As such there are almost no free sugars for competing organisms, potentially removing the need to sterilize the feedstock.</p> | ||
<p>The design of the scaffold has another important feature to improve degradation, because it contains a cellulose binding domain. With the use of molecular dynamics we have <a href="https://2018.igem.org/Team:Groningen/Model/Molecular_Dynamics" target="'_blank">modelled</a> and characterized the affinity of the domain for the cellulose fibers. The cellulose binding domain does not only enhance enzyme proximity to the substrate, but also has benefits for the final bioreactor design. Cellulose-adherence makes it more likely that the genetically modified organism can compete for cellulose with non-adhered microbes. This together with the cellulosome-yeast proximity could potentially remove the need for sterilizing the feedstock in a bioreactor, greatly reducing CO2 emission and costs [1]. </p> | <p>The design of the scaffold has another important feature to improve degradation, because it contains a cellulose binding domain. With the use of molecular dynamics we have <a href="https://2018.igem.org/Team:Groningen/Model/Molecular_Dynamics" target="'_blank">modelled</a> and characterized the affinity of the domain for the cellulose fibers. The cellulose binding domain does not only enhance enzyme proximity to the substrate, but also has benefits for the final bioreactor design. Cellulose-adherence makes it more likely that the genetically modified organism can compete for cellulose with non-adhered microbes. This together with the cellulosome-yeast proximity could potentially remove the need for sterilizing the feedstock in a bioreactor, greatly reducing CO2 emission and costs [1]. </p> | ||
− | <figure><img src="https://static.igem.org/mediawiki/2018/c/c6/T--Groningen--Cellulosome.png"></figure> | + | <figure><img src="https://static.igem.org/mediawiki/2018/c/c6/T--Groningen--Cellulosome.png" class="center"></figure> |
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<p>The second part of our process is production of styrene. There are several steps which the cell can perform endogenously, but some need exogenous aid. In order for glucose to be converted to styrene, it first has to enter the glycolysis where it is converted into phosphoenolpyruvate (PEP). Next, PEP is converted into phenylalanine via the shikimate pathway. For the conversion of phenylalanine to trans-cinnamate, which is the next step in our process, we need to add a catalyst in the form of phenylalanine ammonia lyase 2 (PAL2). Subsequently, the trans-cinnamate is converted into styrene by the endogenous enzyme ferulic acid decarboxylase 1 (FDC1) [10]. </p> | <p>The second part of our process is production of styrene. There are several steps which the cell can perform endogenously, but some need exogenous aid. In order for glucose to be converted to styrene, it first has to enter the glycolysis where it is converted into phosphoenolpyruvate (PEP). Next, PEP is converted into phenylalanine via the shikimate pathway. For the conversion of phenylalanine to trans-cinnamate, which is the next step in our process, we need to add a catalyst in the form of phenylalanine ammonia lyase 2 (PAL2). Subsequently, the trans-cinnamate is converted into styrene by the endogenous enzyme ferulic acid decarboxylase 1 (FDC1) [10]. </p> | ||
− | <figure><img src="https://static.igem.org/mediawiki/2018/2/21/T--Groningen--styrene_pathway.png"><figcaption><i>Figure 2. The phenylalanine to styrene pathway. Phenylalanine is de-aminated by Pal2 to form trans-cinnamate, which is converted to styrene by a Fdc1-catalyzed carboxylation</i></figcaption></figure> | + | <figure><img src="https://static.igem.org/mediawiki/2018/2/21/T--Groningen--styrene_pathway.png" width="100%"><figcaption><i>Figure 2. The phenylalanine to styrene pathway. Phenylalanine is de-aminated by Pal2 to form trans-cinnamate, which is converted to styrene by a Fdc1-catalyzed carboxylation</i></figcaption></figure> |
<p>To increase styrene production, one of the most common strategies is to look for the enzyme with the highest activity. In order to do so one can screen isoenzymes from different organisms and compared their activity. Since PAL2 from <i>Arabidopsis thaliana</i> had the highest enzyme activity in <i>E. coli</i> compared to several other phenylalanine ammonia lyases, we decided to use this enzyme for our project [11]. Earlier work also shows successful styrene production in yeast using this PAL2 enzyme [10].</p> | <p>To increase styrene production, one of the most common strategies is to look for the enzyme with the highest activity. In order to do so one can screen isoenzymes from different organisms and compared their activity. Since PAL2 from <i>Arabidopsis thaliana</i> had the highest enzyme activity in <i>E. coli</i> compared to several other phenylalanine ammonia lyases, we decided to use this enzyme for our project [11]. Earlier work also shows successful styrene production in yeast using this PAL2 enzyme [10].</p> | ||
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<p>Instead of providing the cell with multiple plasmids containing the cellulases, scaffold and PAL2, <a href="https://2018.igem.org/Team:Groningen/Human_Practices#driesseninterview">Prof. Driessen</a> suggested to use CRISPR-Cas9 combined with homologous recombination to introduce our system into the genome. This would make the cellulosome more genetically stable, according to Driessen. Furthermore, this would eliminate the complicated cloning steps needed to create large plasmids for our system. Saccharomyces cerevisiae is excellent at homologous recombination of multiple fragments simultaneously, a property we can take advantage of in our project [12]. By use of this strategy, multiple genes (three cellulases, a scaffold and PAL2) with 60 base pairs overhangs can be transformed simultaneously and subsequently, homologous recombination will take place at the site of the CRISPR-Cas9 induced double strand break. The use of CRISPR-Cas9 has the added benefit of eliminating the need for addition of antibiotics or amino acids to the growth medium. They are no longer necessary for plasmid maintenance or screening, as cells with unrepaired double stranded breaks should not grow and the double stranded break can only be repaired with all fragments combined [13]. This is especially beneficial when our strain will be upscaled towards bioreactor volumes.</p> | <p>Instead of providing the cell with multiple plasmids containing the cellulases, scaffold and PAL2, <a href="https://2018.igem.org/Team:Groningen/Human_Practices#driesseninterview">Prof. Driessen</a> suggested to use CRISPR-Cas9 combined with homologous recombination to introduce our system into the genome. This would make the cellulosome more genetically stable, according to Driessen. Furthermore, this would eliminate the complicated cloning steps needed to create large plasmids for our system. Saccharomyces cerevisiae is excellent at homologous recombination of multiple fragments simultaneously, a property we can take advantage of in our project [12]. By use of this strategy, multiple genes (three cellulases, a scaffold and PAL2) with 60 base pairs overhangs can be transformed simultaneously and subsequently, homologous recombination will take place at the site of the CRISPR-Cas9 induced double strand break. The use of CRISPR-Cas9 has the added benefit of eliminating the need for addition of antibiotics or amino acids to the growth medium. They are no longer necessary for plasmid maintenance or screening, as cells with unrepaired double stranded breaks should not grow and the double stranded break can only be repaired with all fragments combined [13]. This is especially beneficial when our strain will be upscaled towards bioreactor volumes.</p> | ||
− | <figure><img src="https://static.igem.org/mediawiki/2018/0/0b/T--Groningen--crispr_cas.png"><figcaption><i>Source: <a href="https://sites.tufts.edu/crispr/genome-editing/homology-directed-repair" target="_blank">https://sites.tufts.edu/crispr/genome-editing/homology-directed-repair/</a> </i></figcaption></figure> | + | <figure><img src="https://static.igem.org/mediawiki/2018/0/0b/T--Groningen--crispr_cas.png" width="100%"><figcaption><i>Source: <a href="https://sites.tufts.edu/crispr/genome-editing/homology-directed-repair" target="_blank">https://sites.tufts.edu/crispr/genome-editing/homology-directed-repair/</a> </i></figcaption></figure> |
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<p>During our visits to <a href="https://2018.igem.org/Team:Groningen/Human_Practices#avantiuminterview" target="_blank">Avantium</a> and <a href="https://2018.igem.org/Team:Groningen/Human_Practices#photanolinterview" target="_blank">Photanol</a> we saw working bioreactor systems and learned about the challenges of upscaling towards an industrial scale. We decided that designing a bioreactor system for StyGreen is the next logical step towards a working real world application. Our production plant design has three parts: the cellulose preprocessing, the main bioreactor tank and a styrene purification module.</p> | <p>During our visits to <a href="https://2018.igem.org/Team:Groningen/Human_Practices#avantiuminterview" target="_blank">Avantium</a> and <a href="https://2018.igem.org/Team:Groningen/Human_Practices#photanolinterview" target="_blank">Photanol</a> we saw working bioreactor systems and learned about the challenges of upscaling towards an industrial scale. We decided that designing a bioreactor system for StyGreen is the next logical step towards a working real world application. Our production plant design has three parts: the cellulose preprocessing, the main bioreactor tank and a styrene purification module.</p> | ||
+ | |||
+ | <figure><img src="https://static.igem.org/mediawiki/2018/5/59/T--Groningen--bennie-3.png" width="100%"><figcaption><i>Figure 1. Production plant design, consisting of a cellulose preprocessing module (left), a main bioreactor tank (mid) and a styrene purification module (right) </i></figcaption></figure> | ||
+ | |||
<p>In our production plant, the cellulose preprocessing is performed by ball milling which proved to be effective for <a href="https://2018.igem.org/Team:Groningen/Results#cellulose_assay">Recell</a> from <a href="https://2018.igem.org/Team:Groningen/Human_Practices#knninterview" target="_blank">KNN cellulose</a>, our main cellulose supplier. Ball milling also does not require strong chemicals and leads to an increased solubility and more amorphous regions, increasing cellulosome activity [6]. </p> | <p>In our production plant, the cellulose preprocessing is performed by ball milling which proved to be effective for <a href="https://2018.igem.org/Team:Groningen/Results#cellulose_assay">Recell</a> from <a href="https://2018.igem.org/Team:Groningen/Human_Practices#knninterview" target="_blank">KNN cellulose</a>, our main cellulose supplier. Ball milling also does not require strong chemicals and leads to an increased solubility and more amorphous regions, increasing cellulosome activity [6]. </p> | ||
<p>The second part of our production plant is the main bioreactor tank. We chose for a continuous production approach over a batch or fed-batch approach because of two reasons. Firstly, <i>S. cerevisiae</i> only grows slowly on cellulose, which makes growing batches time consuming and less economic. Secondly, continuous production enables us to harvest the styrene without having to destroy the laboriously expressed cellulosomes. The bioreactor contains a biphasic medium of water and an apolar solvent. Ethyl acetate was chosen as it has the right density, doesn’t form micelles and doesn’t denature proteins like other solvents might. The produced styrene has a strong preference for an apolar environment (log P = 2,7) and will therefore localize into the ethyl acetate phase. The difference in density of water and ethyl acetate are just right so that they will mix thoroughly under stirring while separating into two phases once stirring is stopped. The apolar phase can then be siphoned off and be led to the styrene purification module.</p> | <p>The second part of our production plant is the main bioreactor tank. We chose for a continuous production approach over a batch or fed-batch approach because of two reasons. Firstly, <i>S. cerevisiae</i> only grows slowly on cellulose, which makes growing batches time consuming and less economic. Secondly, continuous production enables us to harvest the styrene without having to destroy the laboriously expressed cellulosomes. The bioreactor contains a biphasic medium of water and an apolar solvent. Ethyl acetate was chosen as it has the right density, doesn’t form micelles and doesn’t denature proteins like other solvents might. The produced styrene has a strong preference for an apolar environment (log P = 2,7) and will therefore localize into the ethyl acetate phase. The difference in density of water and ethyl acetate are just right so that they will mix thoroughly under stirring while separating into two phases once stirring is stopped. The apolar phase can then be siphoned off and be led to the styrene purification module.</p> | ||
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<h4>References</h4> | <h4>References</h4> |
Latest revision as of 22:57, 17 October 2018
In the process of designing the route from cellulose to StyGreen, there are many factors to consider. There are several approaches that can be taken to degrade cellulose, metabolic pathways to styrene as well as different interesting sources of cellulose. Discussions with many experts have aided us in making the right choices or adjustments during the design process. Furthermore, we connected with the upstream and downstream processes of our design and approached different stakeholders, connecting our project to cellulose suppliers and styrene buyers.
The production of StyGreen from cellulose is a multi-step pathway. As such, we have the choice of using either one or multiple organisms to perform the different reactions. For example, we could engineer a cellulose degrading organism and a styrene producing organism; these organisms can be co-cultured to produce styrene from cellulose. However, after discussing this idea with experts, we concluded that creation of a single organism performing both steps would be the most efficient and industrially desirable choice. In this manner, we produce a consolidated bioprocessing system which is not currently available. The combined process saves substrate, raw materials and utilities such as separate cellulase enzyme production. Moreover, the complete process could take place in one reactor and, in case of higher overall efficiency, this results in a reduced reactor volume and thus lower capital investment [A]. Hence, our ultimate goal is the production of a single robust cell factory that can grow on cellulose and produce styrene effectively in an industrial bioreactor setting.
Besides ‘wet lab’ experiments, we also modelled parts of our system in the 'dry lab' with help from experts to substantiate or improve our design. Want to know more details about our design? Click on the questions below to find out!
[1] Lynd, L. R., Zyl, W. H. van, McBride, J. E., & Laser, M. (2005). Consolidated bioprocessing of cellulosic biomass: an update. Current Opinion in Biotechnology, 16(5), 577–583. http://doi.org/10.1016/J.COPBIO.2005.08.009 [2] Domozych, D. S., Ciancia, M., Fangel, J. U., Mikkelsen, M. D., Ulvskov, P., & Willats, W. G. (2012). The Cell Walls of Green Algae: A Journey through Evolution and Diversity. Frontiers in Plant Science, 3. doi:10.3389/fpls.2012.00082 <[3] Roostaei, J., Zhang, Y., Gopalakrishnan, K., & Ochocki, A. J. (2018). Mixotrophic Microalgae Biofilm: A Novel Algae Cultivation Strategy for Improved Productivity and Cost-efficiency of Biofuel Feedstock Production. Scientific Reports, 8(1). doi:10.1038/s41598-018-31016-1 [4] Algae Biofuel Market Estimates & Trend Analysis By Application (Transportation, Others), By Region (North America, Europe, Asia Pacific, Rest of World), By Country, And Segment Forecasts, 2018 - 2025. (n.d.). Retrieved from https://www.grandviewresearch.com/industry-analysis/algae-biofuel-market [5] Mandels, M., Hontz, L., Nystrom, J.: Enzymatic Hydrolysis of Waste Cellulose. Biotechnology And Bioengineering 16, 1471-1493 (1974) [6] Da Silva, A., Inoue, H., Endo, T., Yano, S., Bon, E.P.S.: Milling and pretreatment of sugarcane bagasse and straw for enzymatic hydrolysis and ethanol fermentation. Bioresource Technology 101, 7402-7409 (2010) [7] Tianjiao Qu et al.: Ball Milling for Biomass Fractionation and Pretreatment with Aqueous Hydroxide Solutions. ACS Sustainable Chemistry and Engineering 5, 7733-7742 (2017) [8] Percival Zhang, Y. H., Cui, J., Lynd, L. R. and Kuang, L. R. A transition from Cellulose Swelling to Cellulose Dissolution by o-Phosphoric Acid: Evidence from Enzymatic Hydrolysis and Supramolecular Structure. Biomacromolecules, 7, 644-648 (2006) [9] Wen, F., Sun, J., & Zhao, H. (2010). Yeast surface display of trifunctional minicellulosomes for simultaneous saccharification and fermentation of cellulose to ethanol. Applied and Environmental Microbiology, 76(4), 1251–60. http://doi.org/10.1128/AEM.01687-09 [10] McKenna, R., Thompson, B., Pugh, S., & Nielsen, D. R. (2014). Rational and combinatorial approaches to engineering styrene production by Saccharomyces cerevisiae. Microbial Cell Factories, 13(1), 123. http://doi.org/10.1186/s12934-014-0123-2 [11] McKenna, R., & Nielsen, D. R. (2011). Styrene biosynthesis from glucose by engineered E. coli. Metabolic Engineering, 13(5), 544–554. http://doi.org/10.1016/J.YMBEN.2011.06.005 [12] van Leeuwen, J., Andrews, B., Boone, C., & Tan, G. (2015). Rapid and Efficient Plasmid Construction by Homologous Recombination in Yeast. Cold Spring Harbor Protocols, 2015(9), pdb.prot085100. http://doi.org/10.1101/pdb.prot085100 [13] Stovicek, V., Holkenbrink, C., & Borodina, I. (2017). CRISPR/Cas system for yeast genome engineering: Advances and applications. FEMS Yeast Research, 17(5). doi:10.1093/femsyr/fox030 [14] West, R. W., Chen, S. M., Putz, H., Butler, G., & Banerjee, M. (1987). GAL1-GAL10 divergent promoter region of Saccharomyces cerevisiae contains negative control elements in addition to functionally separate and possibly overlapping upstream activating sequences. Genes & Development, 1(10), 1118-1131. doi:10.1101/gad.1.10.1118 [15] Peng, B., Williams, T. C., Henry, M., Nielsen, L. K., & Vickers, C. E. (2015). Controlling heterologous gene expression in yeast cell factories on different carbon substrates and across the diauxic shift: A comparison of yeast promoter activities. Microbial Cell Factories, 14(1). doi:10.1186/s12934-015-0278-5 [16] Liu, C., Men, X., Chen, H., Li, M., Ding, Z., Chen, G., … Xian, M. (2018). A systematic optimization of styrene biosynthesis in Escherichia coli BL21(DE3). Biotechnol Biofuels, 11, 14. http://doi.org/10.1186/s13068-018-1017-z [17] Dragosits, M., & Mattanovich, D. (2013). Adaptive laboratory evolution – principles and applications for biotechnology. Microbial Cell Factories, 12, 64. doi.org/10.1186/1475-2859-12-64 [18] Ferrari, A. R., Gaber, Y., & Fraaije, M. W. (2014). A fast, sensitive and easy colorimetric assay for chitinase and cellulase activity detection. Biotechnology for Biofuels, 7(1), 37. http://doi.org/10.1186/1754-6834-7-37 [19] Kemmere, M. F., Mayer, M. J., Meuldijk, J. and Drinkenburg, A. A. (1999), The influence of 4‐tert‐butylcatechol on the emulsion polymerization of styrene. J. Appl. Polym. Sci., 71: 2419-2422. doi:10.1002/(SICI)1097-4628(19990404)71:14<2419::AID-APP14>3.0.CO;2-W
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