Team:Yale/Project Validate

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!align="center"|[[Team:Yale/Project_Overview|Project Overview]]
!align="center"|[[Team:Yale/Project_Overview|Project Overview]]
!align="center"|[[Team:Yale/Project_Validate|Validate PLA synthesis]]
!align="center"|[[Team:Yale/Project_Validate|Validate PLA synthesis]]

Revision as of 04:07, 28 August 2013

Project Overview Validate PLA synthesis Develop bioassay Apply MAGE Introduce export system Make a bioplastic


Contents

Aims for the Project

  1. Engineer strains of E. coli to validate PLA synthesis
  2. Develop bioassay to screen PLA production
  3. Apply MAGE to optimize PLA production, guided by FBA
  4. Introduce type 1 secretion system to export and extract PLA
  5. Make a bioplastic



Engineer strains of E. coli to validate PLA synthesis

Synthesizing and Assembling the Heterologous Enzymes

  • In order to reproduce the results of the Lee group we needed to insert the two heterologous genes.
  1. Clostridum propionicum propionate CoA transferase (denoted PCT)
  2. Pseudomonas resinovorans polyhydroxyalkanoate synthase (denoted PHA)



Step 1 outline.jpg This was our plan in order to validate PLA synthesis. In order to save money we ordered each of the two heterologous genes in four pieces from IDT giving us 8 GBlocks. Each gene had an inducible promoter in front so we could tightly regulate the expression of the enzyme. The terminators were amplified from other sources and given homology to the appropriate Gblocks.



Here is a schematic of what the entire construct looks like with both promoter, genes and terminators.

GblockPLA.png


Each fragment was amplified using PCR, to give homology to adjacent fragments. Using Gibson assembly, our plan was to assemble all 10 fragments into one construct.

PLAgenes.png


In order to facilitate the process, we used Gibson assembly on each gene separately. Here is a gel of the first 4 Gblocks (labeled PLA1-4), along with the first terminator (labeled T1), and then the 5 pieces assembled together.


PHAgel.JPG PHA.png


Here is a gel of the assembly of the last 4 Gblocks, along with the second terminator.


PCTgel.png PCT.png

Here is a gel of the assembly of the entire construct.


Bothgenegel.png Both genes.png



Sequencing the construct

  • Keck Biotechnology Resource Laboratory kindly sequenced our construct for us
    • Using our Geneious license we aligned the sequencing results with the desired sequence of our construct
    • Here is a zoomed-in picture of the results

Seq.zoomed.png

  • These are the results of the alignment of all 8 fragments with the desired sequence. Ignoring the mismatches at the beginning and end of the sequencing fragments, along with those mismatches covered by the complementary fragment, there appears to only be one legitimate error in our construct. It is denoted below with the red arrow. Fortunately, this happens to fall in a noncoding region of the construct (after the first terminator and before the second promoter).

Wholeseq.png



Inserting via Plasmid

  • In order to insert the two heterologous genes into E. coli, we used Gibson assembly to add our construct onto a plasmid with KanR as a selectable marker.
PZE plasmid.JPG

EcNR2transformPLA.png

Inserting into the Genome

TolC Negative Selection

  • We used a strain with TolC located at 21B, a highly recombinogenic site in the genome (Isaacs et al. 2011). Our plan was to replace TolC with our construct using double stranded DNA recombination, then use colicin E1 negative selection to pick desired cells (DeVito 2007).
TolCnegative.JPG

Positive Selection with KanR

  • Since we had trouble with the TolC negative selection, we decided to pursue an alternative option, which was positive selection.
    • We planned to add kanamycin resistance to the end of our construct and use double-stranded recombination to integrate it into the genome again at site 21B.
KanR positive select.JPG

Screen Shot 2013-08-05 at 10.43.48 AM.png