Team:Washington/Alkanes/Future/LuxCDE

From 2011.igem.org

(Difference between revisions)
(Results)
(Methods)
Line 15: Line 15:
We would design oligos to amplify C, D, and E off of the LuxBrick. Unlike the previous method, the oligos would have sticky ends of [    ] base pairs to prevent misannealing, and the fragment containing C would also contain the vector for ligation. A 3-piece Gibson assembly was then done on C, D, and E, and the product was then transformed into cells.
We would design oligos to amplify C, D, and E off of the LuxBrick. Unlike the previous method, the oligos would have sticky ends of [    ] base pairs to prevent misannealing, and the fragment containing C would also contain the vector for ligation. A 3-piece Gibson assembly was then done on C, D, and E, and the product was then transformed into cells.
-
*<big>Gene Synthesis (Still working on this)</big>
+
*<big>Gene Synthesis</big>
Instead of using the LuxBrick to obtain C, D, and E, we would optimize C, D, and E, then assemble them ourselves. PCR was then used to amplify the respective pieces, and each of the three pieces was then digested and transformed into cells.
Instead of using the LuxBrick to obtain C, D, and E, we would optimize C, D, and E, then assemble them ourselves. PCR was then used to amplify the respective pieces, and each of the three pieces was then digested and transformed into cells.
-
(Still working on this)
+
[Still working on this, will be expanded after experiments are complete]
==Results==
==Results==

Revision as of 23:13, 13 September 2011


Contents

Alternative Routes for Fatty Aldehyde Production

Background

Methods

  • PCR

This method revolved around designing oligos to PCR amplify LuxCD and LuxE off of the LuxBrick; LuxE was not directly adjacent to LuxCD in the Luxbrick, and therefore had to be obtained separately. Sticky ends on the oligos would then allow us to obtain a LuxCDE using stitching PCR. We would then digest and cut the resulting fragment, ligate it into a similarly-cut vector, and use transformation to obtain the desired plasmid with LuxCDE embedded into it.

  • Gibson Assembly (mostly accurate, need to make sure on some stuff)

We would design oligos to amplify C, D, and E off of the LuxBrick. Unlike the previous method, the oligos would have sticky ends of [ ] base pairs to prevent misannealing, and the fragment containing C would also contain the vector for ligation. A 3-piece Gibson assembly was then done on C, D, and E, and the product was then transformed into cells.

  • Gene Synthesis

Instead of using the LuxBrick to obtain C, D, and E, we would optimize C, D, and E, then assemble them ourselves. PCR was then used to amplify the respective pieces, and each of the three pieces was then digested and transformed into cells.

[Still working on this, will be expanded after experiments are complete]

Results

The PCR and Gibson methods failed at multiple steps for uncertain reasons. We hypothesize that LuxCD's abnormally high AT concentration may have caused misannealing for primers, causing primer-dimer errors and other problems, but no concrete evidence exists for this as of yet. For gene assembly, we have lowered the AT concentration of C, D, and E to more optimal levels for PCR.

[Still working on this, will be expanded once all experiments are complete]

Current Status

Parts Submitted