Team:Edinburgh/Results/Glycogen3

From 2008.igem.org

(Difference between revisions)
Line 1: Line 1:
<div id="header">{{Template:Team:Edinburgh/Templates/Header}}</div>
<div id="header">{{Template:Team:Edinburgh/Templates/Header}}</div>
-
'''[[Team:Edinburgh/Results/Glycogen2|< Previous Assay]] | [[Team:Edinburgh/Results|Back to Results]] | [[Team:Edinbrugh/Results/Glycogen 4|Next Assay >]]'''
+
'''[[Team:Edinburgh/Results/Glycogen2|< Previous Assay]] | [[Team:Edinburgh/Results|Back to Results]] | [[Team:Edinbrugh/Results/Glycogen4|Next Assay >]]'''
== Glycogen Assay 3 (Quantitative: Raman) ==
== Glycogen Assay 3 (Quantitative: Raman) ==

Revision as of 22:40, 27 October 2008

< Previous Assay | Back to Results | Next Assay >

Glycogen Assay 3 (Quantitative: Raman)

Raman spectroscopy was performed by Dr Rabah Mouras.

Experiment Design

This quantitative assay compared the amount of glycogen produced by:

  • Sample 1 (Control): E. coli cells with no modification to the glycogen production system and grown in a medium which does not promote glycogen formation. These should have a low, basal level of glycogen.
  • Sample 2: E. coli cells transformed with the glgC16 BioBrick but grown in a glucose-free medium. These should produce a higher level of glycogen than the control.
  • Sample 3: E. coli cells transformed with the glgC16 Biobrick and grown in a high-glucose medium. These should produce the highest level of glycogen.

Results from Glycogen Assay 2 (Qualitative) were in line with these expectations.

The three samples were analysed by Raman spectroscopy to determine the glycogen:protein ratio. Glycogen results in a peak at a Raman shift of 478cm-1, so the Raman intensity of this peak was measured for each sample and compared to the Phenylalanine peak at 1003cm-1.

Results

Edinburgh=Glycogen-Assay3.jpg

The results confirm our expectations. Control cells (S1) produced the least amount of glycogen and glgC16 cells grown in high-glucose medium (S3) the most. From the intensity of the glycogen peak, the concentration of glycogen in S3 is estimated to be 3~4 times more than in S2.

We may thus conclude that the glgC16 BioBrick results in significantly increased production of glycogen, especially in a high-glucose medium.