|
If you are seeing this message, you may be experiencing temporary network problems. Please wait a few minutes and refresh the page. If the problem persists, you may wish to report it to your local Network Manager.
It is also possible that your web browser is not configured or not able to display style sheets. In this case, although the visual presentation will be degraded, the site should continue to be functional. We recommend using the latest version of Microsoft or Mozilla web browser to help minimise these problems.
Wiley InterScience | |||||||||||
  Plant Biotechnology JournalVolume 4 Issue 6, Pages 605 - 622 Published Online: 23 Jun 2006 Journal compilation © 2010 Blackwell Publishing Ltd Plant Biotechnology Journal is published by Wiley-Blackwell in association with the Society for Experimental Biology (SEB) and the Association of Applied Biologists (AAB).
Abstract | References | Full Text: HTML, PDF (Size: 606K) | Supporting Information | Related Articles | Citation Tracking  A synthetic de-greening gene circuit provides a reporting system that is remotely detectable and has a re-set capacity † Present address: Samuel Roberts Noble Foundation, Ardmore, OK 73401, USA ‡These authors contributed equally to this work Copyright © 2006 Blackwell Publishing Ltd KEYWORDS biological sensor • biosensor • chlorophyll • genetic circuit • remote detection reporter • synthetic biology ABSTRACTPlants have evolved elegant mechanisms to continuously sense and respond to their environment, suggesting that these properties can be adapted to make inexpensive and widely used biological monitors, or sentinels, for human threats. For a plant to be a sentinel, a reporting system is needed for large areas and widespread monitoring. The reporter or readout mechanism must be easily detectable, allow remote monitoring and provide a re-set capacity; all current gene reporting technologies fall short of these requirements. Chlorophyll is one of the best-recognized plant pigments with an already well-developed remote imaging technology. However, chlorophyll is very abundant, with levels regulated by both genetic and environmental factors. We designed a synthetic de-greening circuit that produced rapid chlorophyll loss on perception of a specific input. With induction of the de-greening circuit, changes were remotely detected within 2 h. Analyses of multiple de-greening circuits suggested that the de-greening circuit functioned, in part, via light-dependent damage to photosystem cores and the production of reactive oxygen species. Within 24–48 h of induction, an easily recognized white phenotype resulted. Microarray analysis showed that the synthetic de-greening initiated a process largely distinct from normal chlorophyll loss in senescence. Remarkably, synthetically de-greened white plants re-greened after removal of the inducer, providing the first easily re-settable reporter system for plants and the capacity to make re-settable biosensors. Our results showed that the de-greening circuit allowed chlorophyll to be employed as a simple but powerful reporter system useful for widespread areas. Received 22 March 2006; revised 10 May 2006; accepted 11 May 2006. | 
|
|
|
 |
 |
