Team:TU Delft/Project/conclusions

From 2010.igem.org

(Difference between revisions)
(RBS Characterization)
(Sub-projects)
 
(25 intermediate revisions not shown)
Line 2: Line 2:
__NOTOC__
__NOTOC__
==Conclusions==
==Conclusions==
-
Our goal was to tackle the biological conversion of hydrocarbons in an aqueous environment. The basis of the project was generating a "biological chassis", which provides the framework for varying and multiple characteristics needed for the conversion of hydrocarbons, including considerations like conversion ability, hydrocarbon tolerance/solubility and halo (salt) tolerance. This chassis could than be used in for example specifically the biological degradation of oil particles in oil sands tailing water.
+
We have shown that using the concept of BioBricks it is possible to design an organism that ('''1''') reacts to its environment [[Team:TU_Delft/Project/sensing|(sensing)]], ('''2''') influences the solubility of hydrocarbons [[Team:TU_Delft/Project/solubility|(solubility)]] , ('''3''') exhibits a higher tolerance towards solvents and salts [[Team:TU_Delft/Project/tolerance|(survival)]] and ('''4''') implements (parts) of novel pathways [[Team:TU_Delft/Project/alkane-degradation|(alkane degradation)]]. This chassis could be used for example the biological degradation of residual oil in oil sands tailing waters, or the treatment of waste water from the oil industry.  
-
===Alkane Degradation===
+
[[Image:TUDelft_Group.png|center]]
-
===Survival===
+
==Sub-projects==
 +
<html><div style="float:right"><a href="https://2010.igem.org/Team:TU_Delft/Project/alkane-degradation"><img src="https://static.igem.org/mediawiki/2010/2/21/TU_Delft_degradation_icon.jpg" align="right" vspace="5" hspace="5" border="0" /></div></a>
 +
<div style="border: 1px solid #e2b7b6; padding: 5px;">
 +
 +
<h3><a href="https://2010.igem.org/Team:TU_Delft/Project/alkane-degradation" style="color: #9f0f0e;">
 +
Alkane degradation
 +
</a></h3>
 +
 +
</html>
 +
Assays could be developed for the characterization of the enzymes involved in the first step of alkane degradation (AH-system and LadA). The results show a clear difference in enzyme activity between the strains of interest and the negative control. The strain carrying the AH-system had an enzyme activity of 4.49x10<sup>-2</sup> U/mg dry weight, whereas the negative control was 1.23x10<sup>-3</sup> U/mg dry weight. The strain carrying LadA had an enzyme activity of 3.33x10<sup>-3</sup> U/mg total protein, whereas the negative control was 5.49x10<sup>-4</sup> U/mg total protein.
 +
 +
According to our analysis, the enzymatic activities of our recombinant strain and the negative control are statistically different at confidence level of 0.95, which means that the part BBa_K398018 the alcohol dehydrogenase activity by a factor two. We showed that the parts BBa_K398005 and BBa_K398018 have biological activity; particularly when we used BBa_K398018 the enzyme activity of E. coli cell extracts became equivalent to 3% of the in vitro activity of the positive control (''Pseudomonas putida'' OTR1).
 +
 +
Our results also suggest that the recombinant strains ''E. coli'' 029A and ''E. coli'' 030A functionally express our biobricks. The biobrick [http://partsregistry.org/Part:BBa_K398006 BBa_K398006] under the promoter-rbs combination BBa_J23100-BBa_J61117 increases the dodecanal dehydrogenase activity in ''E. coli'' cell extracts 2-fold; whereas the expression of the same protein using the part BBa_J13002 as promoter-rbs combo increases the same activity 3-fold. These enzymatic activities are equivalent to 33.98% and 42.01% of the Pseudomonas putida aldehyde dehydrogenase activity, respectively. For future work we suggest that more research goes into the fine-tuning of the necessary protein production rates. Furthermore, combining this sub-part with the rest of the sub-projects to create the true chassis would be the next step.
 +
 +
<html>
 +
 +
</div>
 +
 +
<br style="clear:both;" /></html>
 +
 +
<html><div style="float:right"><a href="https://2010.igem.org/Team:TU_Delft/Project/sensing"><img src="https://static.igem.org/mediawiki/2010/b/bd/TU_Delft_Sensing_icon.jpg" align="right" vspace="5" hspace="5" border="0" /></a></div>
 +
 +
<div style="border: 1px solid #d2e6bf; padding: 5px;">
 +
 +
<h3><a href="https://2010.igem.org/Team:TU_Delft/Project/sensing" style="color: #6aab2c;">
 +
Sensing
 +
</a></h3></html>
 +
After the pre cultures have been grown in glucose, a switch to alkanes as a sole cabon and energy source is required. Therefore we designed a biobrick switch that can sense the absence of glucose: pCaif.
 +
 +
This new promoter combined with B0032 has a GFP production rate of 3.975E07 GFP molecules/second/O.D. during the stationary phase. Moreover, we demonstrated that this promoter is more active the during stationary phase indicating high cAMP levels. Finally, in the presence of a secondary carbon source the GFP production rate decreases again due to the catabolism of the secondary C-source.
 +
 +
 +
 +
<html></div><br style="clear:both;" /></html>
 +
<html><div style="float:right"><a href="https://2010.igem.org/Team:TU_Delft/Project/tolerance"><img src="https://static.igem.org/mediawiki/2010/5/59/TU_Delft_Tolerance_icon.jpg" align="right" vspace="5" hspace="5" border="0" /></div></a>
 +
 +
<div style="border: 1px solid #b2c0d9; padding: 5px;">
 +
 +
<h3><a href="https://2010.igem.org/Team:TU_Delft/Project/tolerance" style="color: #002f82;">
 +
Survival
 +
</a></h3></html>
====Salt tolerance====
====Salt tolerance====
-
Our biobrick has enabled us to increase the salt tolerance of E.coli by an average of 20%. But due to the range of effects caused by increased salt stress, complete tolerance using a single protein is impossible. As such we hope to have made a first step and that the future iGEM teams will be able to build upon this knowledge.
+
Our biobrick has enabled us to increase the salt tolerance of E.coli by an average of 20%. The presented BioBrick probably reduces one of several effects caused by salt stress. A complete tolerance using a single protein seems unrealistic, a combination of different could further increase the tolerance to salt.
-
===Solubility===
+
====Solvent tolerance====
-
To overcome the mass‐transfer limitation between the water and oil fase, a gene encoding for [[Team:TU_Delft/Project/solubitility/alna|AlnA]], a protein with emulsifying properties was expressed. The [[Team:TU_Delft/Project/solubility/results|increased solubility]] of about 20% was determined by [[Team:TU_Delft/Project/solubility/characterization|a new method]]. We suggest that in future research the protein is tagged, so it can be isolated with higher purity.
+
Our BioBrick has enabled us to increase the solvent tolerance of ''E.coli'' when n-hexane is present in the culture medium at high concentrations. According to our findings, the growth rate of ''E.coli'' is improved 60% at a n-hexane concentration of 10%(v/v).
-
===Sensing===
+
<html></div><br style="clear:both;" /></html>
-
===Anderson RBS Characterizations===
+
<html><div style="float:right"><a href="https://2010.igem.org/Team:TU_Delft/Project/solubility"><img src="https://static.igem.org/mediawiki/2010/9/98/TU_Delft_Solubility_icon.jpg" align="right" vspace="5" hspace="5" border="0" /></div></a>
-
In order to tune the protein expressions of the alkane degrading genes we've characterized 5 members of the Anderson RBS family. The following relative efficiencies were found:
+
 
-
{|
+
<div style="border: 1px solid #e0b2dd; padding: 5px;">
-
|<b>Ribosome binding site</b>
+
 
-
|<b>Mean relative strength</b>
+
<h3><a href="https://2010.igem.org/Team:TU_Delft/Project/solubility" style="color: #990090;">
 +
Solubility
 +
</a></h3></html>
 +
To overcome the mass‐transfer limitation between the water and oil phase, a gene encoding for [[Team:TU_Delft/Project/solubility/parts|AlnA]], a protein with emulsifying properties was expressed. The [[Team:TU_Delft/Project/solubility/results|increased solubility]] is about 20%. The solubility was determined by [[Team:TU_Delft/Project/solubility/characterization|a new method]]. We suggest that in future research the protein is tagged, so it can be isolated with higher purity.
 +
 
 +
<html><br /><br /></div><br style="clear:both;" /></html>
 +
 
 +
<html><div style="float:right"><a href="https://2010.igem.org/Team:TU_Delft/Project/rbs-characterization"><img src="https://static.igem.org/mediawiki/2010/0/06/TU_Delft_RBS_characterization_icon.jpg" align="right" vspace="5" hspace="5" border="0" /></div></a>
 +
 
 +
<div style="border: 1px solid #ffdda8; padding: 5px;">
 +
 
 +
<h3><a href="https://2010.igem.org/Team:TU_Delft/Project/rbs-characterization" style="color: #995e00;">
 +
RBS Characterization
 +
</a></h3></html>
 +
 
 +
In order to fine-tune the protein expressions of the alkane degrading genes we've [https://2010.igem.org/Team:TU_Delft#page=Project/rbs-characterization/characterization characterized] 5 members of the Anderson RBS family using an improved protein production model taking dilution and protein degradation into account. The following relative efficiencies were found:
 +
{|style="color:black; background-color:white;" cellpadding="5" cellspacing="0" border="1"
 +
|<b>RBS</b>
 +
|<b>Efficiency</b>
|-
|-
|[http://partsregistry.org/Part:BBa_J61100 J61100]
|[http://partsregistry.org/Part:BBa_J61100 J61100]
-
|0.03
+
|1.20%
-
|-
+
-
|[http://partsregistry.org/Part:BBa_J61117 J61117]
+
-
|0.12
+
|-
|-
|[http://partsregistry.org/Part:BBa_J61101 J61101]
|[http://partsregistry.org/Part:BBa_J61101 J61101]
-
|0.08
+
|11.9%
|-
|-
|[http://partsregistry.org/Part:BBa_J61107 J61107]
|[http://partsregistry.org/Part:BBa_J61107 J61107]
-
|0.02
+
|7.70%
 +
|-
 +
|[http://partsregistry.org/Part:BBa_J61117 J61117]
 +
|1.26%
|-
|-
|[http://partsregistry.org/Part:BBa_J61127 J61127]
|[http://partsregistry.org/Part:BBa_J61127 J61127]
-
|0.07
+
|6.52%
|-
|-
|[http://partsregistry.org/Part:BBa_B0032 B0032]
|[http://partsregistry.org/Part:BBa_B0032 B0032]
-
|0.30
+
|30.0%
|}
|}
 +
 +
<html></div><br style="clear:both;" /></html>

Latest revision as of 23:35, 27 October 2010

Conclusions

We have shown that using the concept of BioBricks it is possible to design an organism that (1) reacts to its environment (sensing), (2) influences the solubility of hydrocarbons (solubility) , (3) exhibits a higher tolerance towards solvents and salts (survival) and (4) implements (parts) of novel pathways (alkane degradation). This chassis could be used for example the biological degradation of residual oil in oil sands tailing waters, or the treatment of waste water from the oil industry.

TUDelft Group.png

Sub-projects

Alkane degradation

Assays could be developed for the characterization of the enzymes involved in the first step of alkane degradation (AH-system and LadA). The results show a clear difference in enzyme activity between the strains of interest and the negative control. The strain carrying the AH-system had an enzyme activity of 4.49x10-2 U/mg dry weight, whereas the negative control was 1.23x10-3 U/mg dry weight. The strain carrying LadA had an enzyme activity of 3.33x10-3 U/mg total protein, whereas the negative control was 5.49x10-4 U/mg total protein.

According to our analysis, the enzymatic activities of our recombinant strain and the negative control are statistically different at confidence level of 0.95, which means that the part BBa_K398018 the alcohol dehydrogenase activity by a factor two. We showed that the parts BBa_K398005 and BBa_K398018 have biological activity; particularly when we used BBa_K398018 the enzyme activity of E. coli cell extracts became equivalent to 3% of the in vitro activity of the positive control (Pseudomonas putida OTR1).

Our results also suggest that the recombinant strains E. coli 029A and E. coli 030A functionally express our biobricks. The biobrick BBa_K398006 under the promoter-rbs combination BBa_J23100-BBa_J61117 increases the dodecanal dehydrogenase activity in E. coli cell extracts 2-fold; whereas the expression of the same protein using the part BBa_J13002 as promoter-rbs combo increases the same activity 3-fold. These enzymatic activities are equivalent to 33.98% and 42.01% of the Pseudomonas putida aldehyde dehydrogenase activity, respectively. For future work we suggest that more research goes into the fine-tuning of the necessary protein production rates. Furthermore, combining this sub-part with the rest of the sub-projects to create the true chassis would be the next step.


Sensing

After the pre cultures have been grown in glucose, a switch to alkanes as a sole cabon and energy source is required. Therefore we designed a biobrick switch that can sense the absence of glucose: pCaif.

This new promoter combined with B0032 has a GFP production rate of 3.975E07 GFP molecules/second/O.D. during the stationary phase. Moreover, we demonstrated that this promoter is more active the during stationary phase indicating high cAMP levels. Finally, in the presence of a secondary carbon source the GFP production rate decreases again due to the catabolism of the secondary C-source.



Survival

Salt tolerance

Our biobrick has enabled us to increase the salt tolerance of E.coli by an average of 20%. The presented BioBrick probably reduces one of several effects caused by salt stress. A complete tolerance using a single protein seems unrealistic, a combination of different could further increase the tolerance to salt.

Solvent tolerance

Our BioBrick has enabled us to increase the solvent tolerance of E.coli when n-hexane is present in the culture medium at high concentrations. According to our findings, the growth rate of E.coli is improved 60% at a n-hexane concentration of 10%(v/v).


Solubility

To overcome the mass‐transfer limitation between the water and oil phase, a gene encoding for AlnA, a protein with emulsifying properties was expressed. The increased solubility is about 20%. The solubility was determined by a new method. We suggest that in future research the protein is tagged, so it can be isolated with higher purity.




RBS Characterization

In order to fine-tune the protein expressions of the alkane degrading genes we've characterized 5 members of the Anderson RBS family using an improved protein production model taking dilution and protein degradation into account. The following relative efficiencies were found:

RBS Efficiency
J61100 1.20%
J61101 11.9%
J61107 7.70%
J61117 1.26%
J61127 6.52%
B0032 30.0%