Difference between revisions of "Team:UNSW Australia/Results"

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Revision as of 12:22, 17 October 2018

Results

Key Findings

Our project has provided the proof of principle for a prefoldin scaffold that co-localises enzymes. We have proven that our attachment mechanisms (SpyTag/Catcher and Snoop Tag/Catcher) work between enzymes and prefoldin, and that the heterohexameric structure of alpha and beta prefoldin self-assembles.

Results by Section

Cloning

Eight DNA constructs were cloned into pETDuet-1 and pRSFDuet-1 plasmids using Gibson assembly. Six of these constructs were subcloned into pET19b for protein expression. In addition to this, BBa_K1789000 (IaaM) and BBa_K1789001 (IaaH) were cloned into pET19b for protein expression. All recombinant plasmids were validated by a diagnostic digest and Sanger sequencing.

Protein Production

Nine proteins were expressed in Escherichia coli T7 cells and purified using Immobilised Metal Affinity Chromatography (IMAC). These included prefoldin proteins that form the basis of our scaffold, and prefoldin proteins fused with SpyCatcher and SnoopCatcher. Enzymes and fluorescent proteins were expressed and purified, including the enzyme indole acetamide hydrolase (IaaH) with a C-terminal SpyTag for conjugation experiments.

Assembly

The formation of our enzyme-scaffold complex requires two stages of assembly: firstly, the formation of the alpha prefoldin and beta prefoldin hexamer, and secondly the covalent attachment of enzymes to the scaffold through SpyTag/SpyCatcher or SnoopTag/SnoopCatcher reactions. We have assembled alpha and beta prefoldin hexamers and covalently attached the enzyme IaaH-SpyTag to alpha prefoldin and gamma prefoldin scaffolds. Furthermore, we visualised filaments of wild-type gamma prefoldin, gamma prefoldin-SpyCatcher, and gamma prefoldin-SpyCatcher attached to IaaH-SpyTag.

FRET

FRET is a method for assessing the distance between two molecules based on energy transfer between two fluorophores. To assess the distance between enzymes attached to our scaffold we planned to perform FRET using the fluorescent proteins mCerulean3 and mVenus free. FRET was successfully performed for mCerulean3 and mVenus free in solution. However, due to time constraints we were unable to express and purify mCerulean3 or mVenus fused to Spy/Snoop Tags for attachment to our scaffold and use in FRET. Nevertheless, we have obtained the optimum excitation wavelengths for mCerulean3 and mVenus and established a working FRET protocol for future use.

Enzyme assays

Biosynthesis of indole-3-acetic-acid (IAA) is the two-step enzymatic reaction we selected to use as proof of concept of our Assemblase scaffold. To compare reaction efficiency in a scaffolded versus unscaffolded enzyme scenario, we successfully set-up two quantitative assays for determining the concentration of reaction intermediates and products over time. We created standard curves for these assays based on unscaffolded enzyme reactions only due to time constraints. In the future these assays can be utilised to test the effect of enzyme scaffolding to our Assemblase system on protein yield.

Plants

Auxins are plant hormones involved in the regulation of plant growth and development. The biosynthesis of the auxin indole-3-aecetic acid (IAA) was used as a test pathway for our scaffold system, and thus a plant growth assay was developed to investigate the functionality of biosynthetically produced IAA. We successfully observed effects of commercially obtained IAA on plant root growth, namely increased lateral root growth and decreased primary root growth. These results are consistent with reports in the literature. Future work could further optimise the concentration of exogenous IAA added to the plant growth agar, and incorporate IAA produced through our Assemblase system.

Modelling of Enzyme Kinetics

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Molecular Dynamics

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Software

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References

  1. Gibson, D. et al. Enzymatic assembly of DNA molecules up to several hundred kilobases. Nature Methods 6, 343-345 (2009).
  2. Spaepen, S., Vanderleyden, J. & Remans, R. Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 31, 425-448, doi:10.1111/j.1574-6976.2007.00072.x (2007).
  3. Szajdak, L. W. Bioactive Compounds in Agricultural Soils. (Springer International Publishing, 2016).
  4. Ruzicka, K. et al. Ethylene regulates root growth through effects on auxin biosynthesis and transport-dependent auxin distribution.Plant Cell 19, 2197-2212 (2007).
  5. Davies, P. J. Plant Hormones: Biosynthesis, Signal Transduction, Action! , (Springer Netherlands, 2007).
  6. Celenza, J. L., Jr., Grisafi, P. L. & Fink, G. R. A pathway for lateral root formation in Arabidopsis thaliana. Genes Dev 9, 2131-2142 (1995).
  7. Reed, R. C., Brady, S. R. & Muday, G. K. Inhibition of auxin movement from the shoot into the root inhibits lateral root development in Arabidopsis. Plant Physiol 118, 1369-1378 (1998).
  8. Potters, G., Pasternak, T. P., Guisez, Y., Palme, K. J. & Jansen, M. A. Stress-induced morphogenic responses: growing out of trouble? Trends Plant Sci 12, 98-105 (2007).
  9. Davis, T. D. & Haissig, B. E. Biology of Adventitious Root Formation. (Springer US, 2013).
  10. Dunlap, J. R. & Robacker, K. M. Nutrient salts promote light-induced degradation of indole-3-acetic Acid in tissue culture media. Plant Physiol 88, 379-382 (1988).
  11. Nissen, S. J. S., E.J. Stability of IAA and IBA in nutrient medium to several tissue culture procedures. HortScience 25, 800-802 (1990).