1 / 12

Production of Artemisinic acid using engineered yeast

Production of Artemisinic acid using engineered yeast. Journal Club I 7 th July 09 David Roche Charles Fracchia. Summary. Introduction. Materials and Methods Identifying the genes involved in Artemisinin production. Results. Concept of feedback. Discussion.

jesse-parrish
Download Presentation

Production of Artemisinic acid using engineered yeast

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Production of Artemisinic acid using engineered yeast Journal Club I 7th July 09 David Roche Charles Fracchia

  2. Summary • Introduction • Materials and Methods • Identifying the genes involved in Artemisinin production • Results • Concept of feedback • Discussion • How is it relevant to SB? • Conclusions

  3. Introduction • Artemisinin is anti-malarial compound • Currently extracted from the wormwood plant – but not efficient or cheap enough • Copied the biosynthetic pathways into the yeast

  4. Materials and Methods • Green: engineered pathways • Blue: directly upregulated • Purple: indirectly upregulated

  5. Materials and Methods • Increased FPP production by upregulating FPP synthases and downregulating to convertases • Introduced ADS • Cloned P450

  6. M&M: Identifying the ADS genes • They supposed that the enzymes shown in green shared common ancestor enzymes • Compared the genes using BLAST and identified one P450 gene with high homology

  7. Results 50% 2x 5x

  8. The concept of feedback inhibition/activation • Metabolic flux relies on regulation

  9. Discussion • Increase in yield and decrease in production costs • General principle can be applied to production of other compounds, e.g. Taxol – an anti cancer drug, which is normally extracted from the Pacific yew tree. • Good example of metabolic engineering to give a useful product.

  10. Discussion • Laborious process of specially engineering each step. • Not necessarily easily reproducible. To re-engineer for other compounds, must go ‘back to the drawing board.’ • Yield optimization and industrial scale-up still required to reduce prices significantly below their current level.

  11. How is it relevant to SB? • Previous strategies in metabolic engineering seem more of an art with experimentation by trial-and-error. • Keasling approach to the problem was more in line with the principles of Synthetic Biology, using a logical approach for the design. • Used computational modelling to investigate the most efficient mRNA sequence for maximal compound production

  12. Conclusions • Materials and Methods • Results • Concept of feedback • Discussion Duplicate genes Knockout genes Genetic insertion 50% increase for duplication 2x increase for knockout 5x increase for gene insertion Products of a reaction can control their own conversion Engineered approach to metabolic engineering. Basic method can be applied to production of other compounds.

More Related