Difference between revisions of "Part:BBa K738000"

Line 2: Line 2:
 
<partinfo>BBa_K738000 short</partinfo>
 
<partinfo>BBa_K738000 short</partinfo>
  
GFP split into two halves (FA and FB), each of which is fused to MS2 or PP7. FA-MS2 and FB-PP7 then bind to their respective aptamers. FA and FB will give out fluorescence only when they are close enough. With help of RNA scaffold D0, FA and FB will be bring together by binding process between MS2 or PP7 and their respective aptamers. Fluorescence provides strong evidence that the RNA scaffold is functional.
+
Scaffold D0 was constructed from a single RNA module d0, which folded into a duplex with PP7 and MS2 aptamer domains that bind PP7 and MS2 fusion proteins.
Function test of the RNA scaffold D0 has been done through split GFP assay. Pictures blow were taken with confocal microscope (olympus fluoview fv1000)
+
 
+
 
[[Image:Fluorescence protein complementation process.jpg]]
 
[[Image:Fluorescence protein complementation process.jpg]]
 +
[[Image:Secondary structure.jpg]]
 +
[[Image:tertiary structure.jpg]]
 +
Secondary and tertiary structure of RNA scaffold D0
  
 
GFP split into two halves (FA and FB), each of which is fused to MS2 or PP7. FA-MS2 and FB-PP7 then bind to their respective aptamers. FA and FB will give out fluorescence only when they are close enough. With help of RNA scaffold D0, FA and FB will be bring together by binding process between MS2 or PP7 and their respective aptamers. Fluorescence provides strong evidence that the RNA scaffold is functional.  
 
GFP split into two halves (FA and FB), each of which is fused to MS2 or PP7. FA-MS2 and FB-PP7 then bind to their respective aptamers. FA and FB will give out fluorescence only when they are close enough. With help of RNA scaffold D0, FA and FB will be bring together by binding process between MS2 or PP7 and their respective aptamers. Fluorescence provides strong evidence that the RNA scaffold is functional.  

Revision as of 19:41, 25 September 2012

RNA Scaffold generator

Scaffold D0 was constructed from a single RNA module d0, which folded into a duplex with PP7 and MS2 aptamer domains that bind PP7 and MS2 fusion proteins. Fluorescence protein complementation process.jpg Secondary structure.jpg Tertiary structure.jpg Secondary and tertiary structure of RNA scaffold D0

GFP split into two halves (FA and FB), each of which is fused to MS2 or PP7. FA-MS2 and FB-PP7 then bind to their respective aptamers. FA and FB will give out fluorescence only when they are close enough. With help of RNA scaffold D0, FA and FB will be bring together by binding process between MS2 or PP7 and their respective aptamers. Fluorescence provides strong evidence that the RNA scaffold is functional. Function test of the RNA scaffold D0 has been done through split GFP assay. Pictures blow were taken with confocal microscope (olympus fluoview fv1000)

Confocal-Co2.jpg Confocal-Co3.jpg

A Bacteria with FA-MS2 and FB-PP7, but without RNA scaffold D0. B Bacteria with FA-MS2, FB-PP7 and RNA scaffold D0 Fluorescence per OD were measured with plate reader (Synergy H1 Hybrid Reader, bioteck).

Plate reader K738000.jpg

Bacteria with FA, FB and D0 is 1.63±0.05 fold brighter than bacteria with FA and FB but without D0.

Usage and Biology

In cells, multienzymatic pathways are often physically and spatially organized onto scaffolds or clusters or into microcompartments. Spatial organization helps substrates flow between interacting proteins, limits cross-talk between signaling pathways, and increases yields of sequential metabolic reactions. But multi-enzyme pathways in vivo widely used in chemical and medical industry are not naturally. So there is lacking in relative scaffolds used as spatial organization. BBa_K738000 is a discrete engineered RNA module for controling the spatial organization of bound proteins, which is able to make the production of the multi-enzyme pathways more efficient.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]