Team:ETH Zurich/project/overview/summarysimple

From 2014.igem.org

(Difference between revisions)
(/* We are driven by our fascination for the emergence of complexity and try to make these snail shells patterns, called Sierpinski triangles, emerge on our own grid of bacteria. To achieve this goal, we follow a synthetic biology approach : we implem)
(Mosaicoli : from simplicity to complexity with biologic gates)
 
(54 intermediate revisions not shown)
Line 1: Line 1:
-
==   ==
+
<center>
 +
== Mosai''coli'' : from simplicity to complexity with bio''logic'' gates ==
 +
</center>
-
[[File:ETH Zurich snails.jpg|400px|center]]
+
[[File:ETH Zurich snails.jpg|center|400px|thumb|'''Figure 1 A''' Textile Cone Snail ([http://en.wikipedia.org/wiki/Conus_textile ''Conus textile''])<br/>Location: Cod Hole, Great Barrier Reef, Australia<br/>[http://commons.wikimedia.org/wiki/File:Textile_cone.JPG Photographer: Richard Ling (CC-BY-SA 3.0)]]]
-
<h3 style="text-align:center"> What if these surprising patterns on sea snail shells would come from a simple rule, followed by all cells on the shell ? </h3>
+
What if these surprising patterns on sea snail shells would come from a simple rule, followed by all subsection on the shell?
-
For example in the picture below, you can see that the same kind of pattern appears, if every cell decides of its state (white or black) depending on the state of the 3 cells above it.
+
For example <html><a href="</html>#cont<html>" class="circled scrolly" style="text-decoration:none;">in the picture below</a></html>, you can see that a similar pattern can be produced by already a simple rule, in which every cell decides on its state (white or green) depending on the state of the 2 cells above it. This rule is called an XOR gate: If one of the two cells above is ON, the cell below them is ON, if both cells above are ON or if both cells above are OFF, the cell below is OFF.
 +
<br/>
 +
<br/>
-
 
+
As a matter of fact, many of the complex patterns you can see in nature come from simple rules. It is the case for hurricanes, flocks of birds, neural networks etc. We call this phenomenon emergence. Emergent phenomena are not predictable from the initial conditions and this is why they surprise us. If you are interested in emergence of complexity in general, you can read more about the [[Team:ETH_Zurich/project/background|background]] of our project.  
-
[[File:ETH Zurich Rule 90.PNG|center|700px]]
+
<br/>
-
 
+
-
<p style="font-size:1.2em"> As a matter of fact, many of the complex patterns you can see in nature come from simple rules. It is the case for hurricanes, flocks of birds, neural networks... We call this phenomenon emergence. Emergent phenomena are not predictable from the initial conditions and this is why they surprise us. If you are interested in emergence of complexity in general, you can read more about the [[Team:ETH_Zurich/project/background|background]] of our project. </p>
+
<br/>
<br/>
-
We are driven by our fascination for the emergence of complexity and try to make these snail shells patterns, called Sierpinski triangles, emerge on our own grid of bacteria. To achieve this goal, we follow a synthetic biology approach : we implement the rule that leads to emergence of these patterns in the DNA of these bacteria.
+
As a team, we are driven by our fascination for the emergence of complexity and try to make these snail shells patterns, called Sierpinski triangles, emerge on our own grid of bacteria. To achieve this goal we encode the rule that leads to emergence of these patterns in the DNA of these bacteria. This approach, defined Synthetic Biology, is the application of engineering principles to the fundamental components of biology. Here we are using [[Team:ETH_Zurich/project/infopro|information processing principles]] in order to control the path of the information through all cells.
 +
<br/>
<br/>
<br/>
-
===== This way, Mosaicoli not only investigates how a complex pattern can emerge from simple rules, but also develops new tools for controlling communication between cells and implementing reliable biological circuits. For a more detailed description of our goals, go to the [[Team:ETH_Zurich/project/goalsapp#goals| Goals]] section. For an outlook on the possible applications of our project, jump directly to [[Team:ETH_Zurich/project/goalsapp#app|Applications and outlook]] =====
+
This way, Mosaicoli not only endeavors to learn more about how a complex pattern can emerge from simple rules, but also develops new tools for controlling communication between cells and implementing reliable biological circuits. For a more detailed description of our goals, go to the [[Team:ETH_Zurich/project/goals| Goals]] section. For an outlook on the possible applications of our project, jump directly to [[Team:ETH_Zurich/project/applications|Applications and outlook]].

Latest revision as of 00:51, 18 October 2014

Mosaicoli : from simplicity to complexity with biologic gates

Figure 1 A Textile Cone Snail ([http://en.wikipedia.org/wiki/Conus_textile Conus textile])
Location: Cod Hole, Great Barrier Reef, Australia
[http://commons.wikimedia.org/wiki/File:Textile_cone.JPG Photographer: Richard Ling (CC-BY-SA 3.0)]


What if these surprising patterns on sea snail shells would come from a simple rule, followed by all subsection on the shell?

For example in the picture below, you can see that a similar pattern can be produced by already a simple rule, in which every cell decides on its state (white or green) depending on the state of the 2 cells above it. This rule is called an XOR gate: If one of the two cells above is ON, the cell below them is ON, if both cells above are ON or if both cells above are OFF, the cell below is OFF.

As a matter of fact, many of the complex patterns you can see in nature come from simple rules. It is the case for hurricanes, flocks of birds, neural networks etc. We call this phenomenon emergence. Emergent phenomena are not predictable from the initial conditions and this is why they surprise us. If you are interested in emergence of complexity in general, you can read more about the background of our project.

As a team, we are driven by our fascination for the emergence of complexity and try to make these snail shells patterns, called Sierpinski triangles, emerge on our own grid of bacteria. To achieve this goal we encode the rule that leads to emergence of these patterns in the DNA of these bacteria. This approach, defined Synthetic Biology, is the application of engineering principles to the fundamental components of biology. Here we are using information processing principles in order to control the path of the information through all cells.

This way, Mosaicoli not only endeavors to learn more about how a complex pattern can emerge from simple rules, but also develops new tools for controlling communication between cells and implementing reliable biological circuits. For a more detailed description of our goals, go to the Goals section. For an outlook on the possible applications of our project, jump directly to Applications and outlook.