Revision as of 19:20, 25 October 2010

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BacillaFilla: Fixing cracks in Concrete

Project Description

BacillaFilla, an engineered Bacillus subtilis, aims to repair microcracks in concrete, which can cause catastrophic structural failure. BacillaFilla would be applied to structures by spraying onto their surface. BacillaFilla swims deep into the microcracks. Repair is effected by production of CaCO₃, filamentous Bacillus subtilis cells and levansucrose. CaCO₃ expands at the same rate as concrete, making it the ideal filler. A filamentous cell mesh provides reinforcement. Levansucrose glues CaCO₃ and filamentous cells in place. B. subtilis 168 sporulates, making it ideal for storage and transportation. The cells are naturally tolerant to concrete's high pH. We designed a swarming part for repairing B. subtilis 168's defective swrA and sfp genes and regaining motility. At the end of the crack the quorum sensing peptide subtilin triggers a co-ordinated population response from a subtilin-inducible promoter. Upregulating SR1 and rocF promotes arginine and urea production, increasing exogenous CaCO₃ deposition. Over-producing YneA induces the filamentous cell phenotype, while SacB converts extracellular sucrose to levansucrose glue.

To protect the environment our project will also include a design for a kill switch.

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 BacillaFilla, an engineered ''Bacillus subtilis'', aims to repair [[Team:Newcastle/problem|microcracks in concrete]], which can cause catastrophic structural failure. BacillaFilla would be applied to structures by spraying onto their surface.
 BacillaFilla swims deep into the microcracks. Repair is effected by production of CaCO<sub>3</sub>, [[Team:Newcastle/Filamentous_Cells| filamentous ''Bacillus subtilis'' cells]] and [[Team:Newcastle/glue|levansucrose]]. [[Team:Newcastle/Urease| CaCO<sub>3</sub>]] expands at the same rate as concrete, making it the ideal filler. A filamentous cell mesh provides reinforcement. Levansucrose glues CaCO<sub>3</sub> and filamentous cells in place.
-''B. subtilis'' 168 sporulates, making it ideal for storage and transportation. The cells are naturally tolerant to concrete's high pH. We repaired ''B. subtilis'' 168's defective [[Team:Newcastle/Swarming|swrA and sfp ]], regaining motility. At the end of the crack the quorum sensing peptide [[Team:Newcastle/End_of_crack_%26_signalling_system|subtilin]] triggers a co-ordinated population response from a [[Team:Newcastle/End_of_crack_%26_signalling_system#2008Brick|subtilin-inducible promoter]]. Upregulating SR1 and rocF promotes arginine and urea production, increasing exogenous  CaCO<sub>3</sub> deposition. Over-producing  YneA induces  the filamentous cell phenotype, while SacB converts extracellular sucrose to levansucrose glue.
+''B. subtilis'' 168 sporulates, making it ideal for storage and transportation. The cells are naturally tolerant to concrete's high pH. We designed a swarming part for repairing ''B. subtilis'' 168's defective [[Team:Newcastle/Swarming|swrA and sfp]] genes and regaining motility. At the end of the crack the quorum sensing peptide [[Team:Newcastle/End_of_crack_%26_signalling_system|subtilin]] triggers a co-ordinated population response from a [[Team:Newcastle/End_of_crack_%26_signalling_system#2008Brick|subtilin-inducible promoter]]. Upregulating SR1 and rocF promotes arginine and urea production, increasing exogenous  CaCO<sub>3</sub> deposition. Over-producing  YneA induces  the filamentous cell phenotype, while SacB converts extracellular sucrose to levansucrose glue.
 To protect the environment our project will also include a design for a [[Team:Newcastle/Non-target-environment_kill_switch| kill switch]].