Team:UiOslo Norway/Project

From 2014.igem.org

(Difference between revisions)
 
(6 intermediate revisions not shown)
Line 17: Line 17:
</div>
</div>
-
<div class="container">
+
</div>
<div class="row">
<div class="row">
<p><img class="img-responsive" src="https://static.igem.org/mediawiki/2014/d/d8/UiO_Oslo_signalingmechanism.png"></p>
<p><img class="img-responsive" src="https://static.igem.org/mediawiki/2014/d/d8/UiO_Oslo_signalingmechanism.png"></p>
</div>
</div>
-
</div>
 
-
</div>
 
<div class="row">
<div class="row">
<div class="col-md-12">
<div class="col-md-12">
Line 52: Line 50:
<div class="col-md-12">
<div class="col-md-12">
<h3>Selection Mechanism</h3>
<h3>Selection Mechanism</h3>
-
<p>By using a split enzyme which is active only when the different parts are assembled, the enzyme activity is an obvious marker of a succesful surface interaction between the bacteria. To succesfully establish a selection mechanism we also needed the bacteria to respond to the enzyme activity. We therefore wanted an enzyme which substrate could induce a particular response in the bacteria that the enzyme product could not. If the presence of the substrate could kill the bacteria and the presence of the product could not, the enzyme activity could protect the interacting bacteria and do the job as a selection mechanism.</p>
+
<p>The enzyme activity is an obvious marker of a succesful surface interaction between the bacteria. We therefore wanted an enzyme which substrate could induce a particular response that the product could not. The enzyme activity could protect the interacting bacteria and do the job as a selection mechanism.</p>
</div>
</div>
</div>
</div>
Line 58: Line 56:
<div class="col-md-12">
<div class="col-md-12">
<h3>The Details</h3>
<h3>The Details</h3>
-
<p>We choose to use β-galactosidase as our enzyme and β-galactosyl glycerol as our substrate. β-galactosyl glycerol is a small β-galatoside that can cross the <em>E.coli</em> membranes and enter cytoplasma through a constitutively expressed galactose permease. β-galactosyl glycerol can also bind to the Lac operon repressor in the same manner as allolactose and inhibit its repressor activity – thus function as an inducer of the Lac operon. β-galactosyl glycerol also makes a potential substrate for β-galactosidase which splits β-galactosyl glycerol into glycerol and galactose<sup>1</sup>.</p>
+
<p>We chose β-galactosidase as our enzyme and β-galactosyl glycerol as our substrate. β-galactosyl glycerol is a small β-galatoside that can cross the <em>E.coli</em> membranes and enter the cytoplasm through a constitutively expressed galactose permease. β-galactosyl glycerol can also bind to the Lac operon repressor in the same manner as allolactose and inhibit its repressor activity – thus function as an inducer of the Lac operon. β-galactosyl glycerol also makes a potential substrate for β-galactosidase which splits β-galactosyl glycerol into glycerol and galactose<sup>1</sup>.</p>
-
<p>A toxic gene under the control of the Lac promoter would therefore kill cells that are not able to cleave β-galactosyl glycerol.</p>
+
<p>β-galactosidase is expressed in wild type <em>E.coli</em> from the LacZ gene which is a part of the Lac operon. β-galactosidase can be split into two different parts with an intact tertiary structure and is therefore a good alternative for our split enzyme. The two parts are coded by what has been called LacZ α and LacZ Ω.</p>
<p>β-galactosidase is expressed in wild type <em>E.coli</em> from the LacZ gene which is a part of the Lac operon. β-galactosidase can be split into two different parts with an intact tertiary structure and is therefore a good alternative for our split enzyme. The two parts are coded by what has been called LacZ α and LacZ Ω.</p>
-
<p>The final version of the microorganizer system would be as follows: Two different strains of bacteria would express a fusion protein consisting of the membrane part of an autotransporter and one of either LacZ α or LacZ Ω. Both strains would also have a toxic gene under the control of the Lac promoter. The two strains would be mixed in a medium containing β-galactosyl glycerol. Bacteria with no partners would have β-galactosyl glycerol flowing into cytoplasma and induce transcription from the Lac promoter and kill them. Bacteria that are bound to each other through the β-galactosidase parts will cleave galactosyl glycerol into galactose and glycerol and make sure the bacteria can survive.</p>
+
<p>The final version of the microorganizer system would be as follows: two different strains of bacteria would express a fusion protein consisting of the membrane part of an autotransporter and one of either LacZ α or LacZ Ω. Both strains would also have a toxic gene under the control of the Lac promoter. The two strains would be mixed in a medium containing β-galactosyl glycerol. Bacteria with no partners would have β-galactosyl glycerol flowing into cytoplasma and induce transcription from the Lac promoter and kill them. Bacteria that are bound to each other through the β-galactosidase parts will cleave galactosyl glycerol into galactose and glycerol and make sure the bacteria can survive.</p>
<p>To avoid a short cut in the mechanism we would have to use bacteria were the Lac operon is deleted so there is no cytoplasmic β-galactosyl activity. We identified a strain, <em>E. coli</em> NCM17, which meet this criteria.</p>
<p>To avoid a short cut in the mechanism we would have to use bacteria were the Lac operon is deleted so there is no cytoplasmic β-galactosyl activity. We identified a strain, <em>E. coli</em> NCM17, which meet this criteria.</p>
</div>
</div>

Latest revision as of 15:39, 17 October 2014

UiOslo IGEM 2014

Project Details

Our Project - The microOrganizer

The aim of our project was to build a system for physically connecting different bacteria in a predetermined manner. We have tried to design surface markers that enable bacteria to bind to each other and to respond to the binding by a mechanism that would allow us to select for bound bacteria. A succesful system would allow us to organize different types of bacteria in a culture and we have therefore named our project «The microOrganizer».

The Parts

Split Enzyme Principle

A split enzyme is an enzyme split into two or more non-functional parts with intact tertiary structure. This means that the enzyme can be active if the different parts come together and assemble into the original enzyme. The enzyme parts have a natural affinity for each other and can assemble spontanously. We wanted to expose two different parts of a split enzyme on the surface of different bacteria.

microOrganizer

Autotransporters

Wild type E.coli can express proteins on their surface by using protein channeling systems called autotransporters. These proteins assemble themselves to a channel in the bacterial membrane and any proteins connected to them will be threaded through this channel and exposed to the outside of the bacteria. The channel itself functions as a membrane anchor. We aimed to connect our split enzyme parts to the membrane part of the autotransporter and present them on the bacterial surface.

Selection Mechanism

The enzyme activity is an obvious marker of a succesful surface interaction between the bacteria. We therefore wanted an enzyme which substrate could induce a particular response that the product could not. The enzyme activity could protect the interacting bacteria and do the job as a selection mechanism.

The Details

We chose β-galactosidase as our enzyme and β-galactosyl glycerol as our substrate. β-galactosyl glycerol is a small β-galatoside that can cross the E.coli membranes and enter the cytoplasm through a constitutively expressed galactose permease. β-galactosyl glycerol can also bind to the Lac operon repressor in the same manner as allolactose and inhibit its repressor activity – thus function as an inducer of the Lac operon. β-galactosyl glycerol also makes a potential substrate for β-galactosidase which splits β-galactosyl glycerol into glycerol and galactose1.

β-galactosidase is expressed in wild type E.coli from the LacZ gene which is a part of the Lac operon. β-galactosidase can be split into two different parts with an intact tertiary structure and is therefore a good alternative for our split enzyme. The two parts are coded by what has been called LacZ α and LacZ Ω.

The final version of the microorganizer system would be as follows: two different strains of bacteria would express a fusion protein consisting of the membrane part of an autotransporter and one of either LacZ α or LacZ Ω. Both strains would also have a toxic gene under the control of the Lac promoter. The two strains would be mixed in a medium containing β-galactosyl glycerol. Bacteria with no partners would have β-galactosyl glycerol flowing into cytoplasma and induce transcription from the Lac promoter and kill them. Bacteria that are bound to each other through the β-galactosidase parts will cleave galactosyl glycerol into galactose and glycerol and make sure the bacteria can survive.

To avoid a short cut in the mechanism we would have to use bacteria were the Lac operon is deleted so there is no cytoplasmic β-galactosyl activity. We identified a strain, E. coli NCM17, which meet this criteria.

Sources

1) Egel, R. (1988) The "lac" operon: an irrelevant paradox? Trends in Genetics 4:31.