Journal of Biological Engineering (Jun 2012)

A BioBrick compatible strategy for genetic modification of plants

  • Boyle Patrick M,
  • Burrill Devin R,
  • Inniss Mara C,
  • Agapakis Christina M,
  • Deardon Aaron,
  • DeWerd Jonathan G,
  • Gedeon Michael A,
  • Quinn Jacqueline Y,
  • Paull Morgan L,
  • Raman Anugraha M,
  • Theilmann Mark R,
  • Wang Lu,
  • Winn Julia C,
  • Medvedik Oliver,
  • Schellenberg Kurt,
  • Haynes Karmella A,
  • Viel Alain,
  • Brenner Tamara J,
  • Church George M,
  • Shah Jagesh V,
  • Silver Pamela A

DOI
https://doi.org/10.1186/1754-1611-6-8
Journal volume & issue
Vol. 6, no. 1
p. 8

Abstract

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Abstract Background Plant biotechnology can be leveraged to produce food, fuel, medicine, and materials. Standardized methods advocated by the synthetic biology community can accelerate the plant design cycle, ultimately making plant engineering more widely accessible to bioengineers who can contribute diverse creative input to the design process. Results This paper presents work done largely by undergraduate students participating in the 2010 International Genetically Engineered Machines (iGEM) competition. Described here is a framework for engineering the model plant Arabidopsis thaliana with standardized, BioBrick compatible vectors and parts available through the Registry of Standard Biological Parts (http://www.partsregistry.org). This system was used to engineer a proof-of-concept plant that exogenously expresses the taste-inverting protein miraculin. Conclusions Our work is intended to encourage future iGEM teams and other synthetic biologists to use plants as a genetic chassis. Our workflow simplifies the use of standardized parts in plant systems, allowing the construction and expression of heterologous genes in plants within the timeframe allotted for typical iGEM projects.

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