Team:BCCS-Bristol/Wetlab/Beads

From 2010.igem.org

(Difference between revisions)
(Beads)
(Beads)
Line 1: Line 1:
{{:Team:BCCS-Bristol/Header}}
{{:Team:BCCS-Bristol/Header}}
-
==Beads==
+
=Beads=
-
Why beads? make the case for encapsulation, subpages for specifics:
 
-
[[:Team:BCCS-Bristol/Wetlab/Beads/Gellan]]
+
One of the factors that differentiate us from other teams is our use of technology to facilitate using our bacteria safely and more effectively in real life situations. More specifically; we encapsulated our bacteria in a non-toxic gel substances, forming beads of highly concentrated bacteria.
-
[[:Team:BCCS-Bristol/Wetlab/Beads/Safety_Benefits]]
 
-
[[:Team:BCCS-Bristol/Wetlab/Beads/Procedure]]
 
-
[[:Team:BCCS-Bristol/Wetlab/Beads/Improvements]]
+
'''Why did we do this?'''
-
[[:Team:BCCS-Bristol/Wetlab/Beads/Encapsulation_Applications]]
 
 +
Initial soil visibility experiments (see [https://2010.igem.org/Team:BCCS-Bristol/Wetlab/signal_soil here]) raised the major problem that high levels of cell death when ''E. coli'' were spread freely in the soil resulted in very low signals. This isn't surprising, given lab-grade ''E. coli'' are deliberately synthesised such that they can't survive outside of very specific conditions, and are easily outcompeted by naturally occuring soil bacteria.
-
There are several reasons why the E. coli cells are encapsulated in a gel bead. The primary
 
-
concerns were visibility of the fluorescent signal and being able to keep the cells separated from the
 
-
environment. There are secondary benefits too, it is possible to include nutrients in the gels for the
 
-
bacteria to consume and the beads can help to absorb nitrates from the soil.
 
-
Initial experiments looking at the visibility of E. coli constitutively expressing GFP on soil, e.g.
+
Whilst developed to solve this problem, our beads have a number of beneficial features:
-
fig. 2, showed that it would be difficult to observe fluorescence from E. coli simply sprayed onto soil
+
-
in solution. The lab-grade E. coli are designed to be out-competed by naturally occurring bacteria
+
-
and they are unable to synthesise certain amino acids. This is designed as a safety feature, it ensures
+
-
that they will not survive for long outside of a lab environment. This means that when sprayed
+
-
directly onto unsterilised soil the E. coli will die relatively quickly, so only those that survive will
+
-
be able to sense nitrate and produce a signal. The bead provides a protective environment for the
+
-
E. coli and packages a large amount of them together to produce a large signal. The bead can also
+
-
be infused with a nutrient broth to provide the cells with an adequate supply of energy and amino
+
-
acids to ensure survival and continued production of GFP and RFP.
+
-
Initial experiments using beads that had just the PyeaR+GFP BioBrick showed that the in-
+
* Beads provide a protective environment, reducing cell death.
-
crease in fluorescence is easily detectable, before and after images can be seen in fig. 4. The beads
+
* Large concentrations of cells in a small area ensure high, easily detectable signals.
-
were placed on wet unsterilised soil that had been saturated with a 20nM potassium nitrate solu-
+
* Nutrients can be added to beads, further improving bacteria survival.
-
tion. There is some fluorescence in the ’before’ picture, this is due to ’leakage’ expression of GFP,
+
* Bacteria are kept seperate from the environment, reducing public safety fears.
-
i.e. the residual expression in the absence of nitrate due to the repressor not repressing every singleP
+
* Increased access to Nitrate.
-
yeaR site.
+
-
It is expected that the beads will limit the spread of E. coli into the field. Since the E. coli
+
 
-
are dependant upon amino acids in their nutrient broth they should not last too long outside of
+
 
-
the bead environment, and when they have exhausted their supply internally they should die off
+
'''More Information'''
-
too. This factor of the bead design has not been rigorously experimentally tested though. It is
+
 
-
unclear exactly how densely packed the E. coli are in the bead, and how much movement they
+
 
-
have, preliminary data from high magnification confocal microscopy that those at the edge of the
+
We hope our work on bacterial encapsulation will prove useful to teams in the future - as encapsulation has a number of applications beyond our soil sensor - so have provided below information on the material we chose to use, and the exact procedure for making beads. Here you can also find links to experiments analysing the performance of beads containing our new biobrick, and our projected costs:
-
bead can move out of it quite freely.
+
 
 +
 
 +
 
 +
<center> • [[:Team:BCCS-Bristol/Wetlab/Beads/Gellan |Bead Materials]] • [[:Team:BCCS-Bristol/Wetlab/making_beads|Making Beads]] •
 +
[[:Team:BCCS-Bristol/Wetlab/Beads|Overview]] • [[:Team:BCCS-Bristol/Wetlab/difference_solution|Beads in Solution]] • [[:Team:BCCS-Bristol/Wetlab/difference_soil|Beads in Soil]] • </center>

Revision as of 14:51, 27 October 2010

Beads

One of the factors that differentiate us from other teams is our use of technology to facilitate using our bacteria safely and more effectively in real life situations. More specifically; we encapsulated our bacteria in a non-toxic gel substances, forming beads of highly concentrated bacteria.


Why did we do this?


Initial soil visibility experiments (see here) raised the major problem that high levels of cell death when E. coli were spread freely in the soil resulted in very low signals. This isn't surprising, given lab-grade E. coli are deliberately synthesised such that they can't survive outside of very specific conditions, and are easily outcompeted by naturally occuring soil bacteria.


Whilst developed to solve this problem, our beads have a number of beneficial features:

  • Beads provide a protective environment, reducing cell death.
  • Large concentrations of cells in a small area ensure high, easily detectable signals.
  • Nutrients can be added to beads, further improving bacteria survival.
  • Bacteria are kept seperate from the environment, reducing public safety fears.
  • Increased access to Nitrate.


More Information


We hope our work on bacterial encapsulation will prove useful to teams in the future - as encapsulation has a number of applications beyond our soil sensor - so have provided below information on the material we chose to use, and the exact procedure for making beads. Here you can also find links to experiments analysing the performance of beads containing our new biobrick, and our projected costs:


Bead MaterialsMaking BeadsOverviewBeads in SolutionBeads in Soil