The 2007 Virginia Genetically Engineered Machine Team 2007 iGEM Jamboree 3 Nov ynthetic_biology.html
The 2007 VGEM Team University-wide, interdisciplinary science and engineering collaboration among students and faculty Amy, George, Kevin, Ranjan, and Emre
Advisors Ron Bauerle Jason Papin Brianne Ray Kay Christopher Erik Fernandez
Birth of the Team First UVA iGEM team Founded, organized and run by us 16 undergraduates applied We raised $50,000 and secured lab space No prior synthetic biology research at UVA We taught ourselves basic synthetic biology
Project Brainstorming Bacterial melanogenesis Ethylene biosensing Autonomous drug delivery Cellular photosignalling Directed angiogenesis Nature Jan 20;403(6767): stry/faculty/muyskensmark mals/newsid_ / stm
Butanol Biosynthesis: Background & Motivation 90 years ago- Butanol first produced in a lab setting via fermentation 1950s- Butanol produced petrochemically due to lowered cost Today- Need for alternate energy source BP DuPont Biofuels. www2.dupont.com/Biofuels/en_US/index.
Butanol Biosynthesis: Background & Motivation Advantages of Butanol over Ethanol Less corrosive Lower latent heat of vaporization Higher energy density Less hygroscopic Fits within current infrastructure Liquid at atmospheric temperature and pressure Easily blends with other fuels Can be used in existing internal combustion engines /index.php/Biobutanol
Butanol Biosynthesis: Background & Motivation Butanol is renewable! However, production is not currently economically feasible More research is necessary High cost of substrate Toxicity to the fermenting organisms
Butanol Biosynthesis: Objectives Design, model, and modularly construct a metabolic pathway in E. coli that includes the following: A butanol-producing metabolic pathway From Clostridium acetobutylicum A cellulase system (cheap carbon source) Select enzymes from Saccharophagus degradans Proteorhodopsin, a light metabolism system (free energy) Discovered via marine metagenomic analysis Increase E.coli butanol tolerance via engineering and/or evolution
BioBrick construction plan
Proteorhodopsin Requires retinal Added to media, not biosynthesized Martinez, A., A. Bradley, J. Waldbauer, R. Summons and E. F. DeLong Proteorhodopsin photosystem gene expression enables photophosphorylation in a heterologous host. PNAS.
Proteorhodopsin Results
Results: Butanol Tolerance Typical Tolerance: % (vol/vol) Unable to get consistent results At higher butanol concentrations (>1.2%), occasionally cells would survive These cells were unable to keep butanol tolerance and would be killed if transferred to a new broth
Mathematical Model Model → experiment → model → etc. Metabolic pathway → stoichiometric matrix Flux balance analysis Fermentation products Pathway bottlenecks Knockout simulations
Mathematical Model
Conclusions Cellulases and butanol-producing enzymes may be toxic to E. coli Simple directed evolution of E. coli may not be an effective way of increasing butanol tolerance Proteorhodopsin is a potential energy- provider for chemical synthesis in E. coli under anaerobic conditions
Ongoing Work Determine what went wrong with our BioBrick construction and whether or not they are lethal to E. coli If possible, assemble BioBricks into composite systems Incorporate better or more membrane-associated solvent efflux pumps to increase tolerance Incorporate the retinal pathway Incorporate more diverse cellulases Complete the central butanol biosynthesis pathway Design and optimize complete bioprocess
Improvements Expansion of the team to include more departments at UVA (materials science, electrical engineering, chemistry) Future funding by corporate sponsorship Potential intro synthetic biology course to educate new researchers and spread the word. Better communication with iGEM personnel and other teams (more community-oriented) to solve common problems
Acknowledgements Our advisors: Erik Fernandez, Jason Papin, Ron Bauerle, Brianne Ray, and Kay Christopher Our academic sponsors: Office of the VP for Research, School of Engineering, U.Va. Engineering Foundation, School of Medicine, and the departments of Biomedical Engineering, Chemical Engineering, Biology, and Microbiology Our corporate sponsor: DNA2.0
References [1] Andrykovitch, G., & Marx, I. (1988). Isolation of a new polysaccharide-digesting bacterium from a salt marsh. Applied and Environmental Microbiology, 54(4), [2] Beja, O., Aravind, L., Koonin, E., Suzuki, M., Hadd, A., Nguyen, L., et al. (2000). Bacterial rhodopsin: Evidence for a new type of phototrophy in the sea. Science, 289(5486), [3] Borden, J., & Papoutsakis, E. (2007). Dynamics of genomic-library enrichment and identification of solvent tolerance genes for clostridium acetobutylicum. Applied and Environmental Microbiology, 73(9), [4] Martinez, A., Bradley, A. S., Waldbauer, J. R., Summons, R. E., & DeLong, E. F. (2007). Proteorhodopsin photosystem gene expression enables photophosphorylation in a heterologous host. Proceedings of the National Academy of Sciences, 104(13), [5] Nolling, J., Breton, G., Omelchenko, M., Makarova, K., Zeng, Q., Gibson, R., et al. (2001). Genome sequence and comparative analysis of the solvent-producing bacterium clostridium acetobutylicum. The Journal of Bacteriology, 183(16), [6] Taylor, L.,II, Henrissat, B., Coutinho, P., Ekborg, N., Hutcheson, S., & Weiner, R. (2006). Complete cellulase system in the marine bacterium saccharophagus degradans strain 2-40T. The Journal of Bacteriology, 188(11),
Thanks for your time! Questions?
Supplemental Materials
Experimental Design
Experiment 1: Testing Alcohol Dehydrogenase aad, aad2 + alcohol dehydrogenase? aad, aad2
Experiment 2: Butanol biosynthesis from butyric acid atoA atoD
Experimental Design Summary: Butyrate to Butanol
Experimental Design Summary: Central Pathway
Experiment 3: Cellulose as an Alternate Energy Source cellobiohydrolase, cellobiase Native
Experiment 4: Proteorhodopsin as Alternate Energy Source
BioBrick Components BioBrick BBa_I BBa_I BBa_I BBa_I BBa_I BBa_I BBa_I BBa_I BBa_I BBa_I Name Proteorhodopsin Cel5F Cel6A Bgl3C CAP0078 ato aad/adhE aad2/adhE1 alde CAC1869 Description Light-activated proton pump Endo-1,4-β-glucanase Cellobuihydrolase Cellobiase Thiolase Acetoacetyl-CoA transferase Butyraldehyde dehydrogenase Butanol dehydrogenase Regulatory factor (↑tolerance?) Source Marine metagenomic analysis Saccharophagus degradans Clostridium acetobutylicum Escherichia coli Clostridium acetobutylicum Ref. [2], [4] [1], [6] [5] [?] [5] [3]