Tokyo/Model
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| - | == | + | ==Balanced Redifferentiation of E.coli ! == |
| - | + | ''' To follow Pareto’s principle found in an [[Tokyo/Concepts|ant society]], our model system must satisfy the three conditions shown in Fig. 1 to 4. In our model, all individual cells have the same genetic circuits but take either of stable state A (worker) or B (idler) depending on the surrounding circumstances as if they are DIFFERENTIATE. They also change their states as if they DEDIFFERENTIATE and REDIFFERENTIATE so that the ratio of the two cell states is well balanced. | |
| - | + | ''' ([http://en.wikipedia.org/wiki/Pareto_principle What is Pareto's principle? (Wikipedia)]) | |
| - | + | ||
| - | ''' To follow Pareto’s principle | + | |
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<br>'''As shown in Fig. 1, 2, 3, and 4, the condition of the system is changing as follows:'''<br><br> | <br>'''As shown in Fig. 1, 2, 3, and 4, the condition of the system is changing as follows:'''<br><br> | ||
| - | '''Bistable state ⇒ The removal of A (worker) ⇒ | + | '''Bistable state ⇒ The removal of A (worker) ⇒ Dedifferentiation of B(idlers)⇒ Balanced Redifferentiation into A and of B''' |
<br><br> | <br><br> | ||
| - | [[Image:1state.JPG|thumb| | + | [[Image:1state.JPG|thumb|210px|'''Fig. 1 Condition 1. Bistable state at balanced ratio of differentiated A and B''' <br>The system is stable when it contains both A (worker) and B (idler) "balanced" at certain ratio.|left]] |
[[Image:2state.JPG|thumb|190px|'''Fig. 2 Condition 2. Removal of A''' <br>Now that A (worker) is removed, there is only B (idler) left.|center|left]] | [[Image:2state.JPG|thumb|190px|'''Fig. 2 Condition 2. Removal of A''' <br>Now that A (worker) is removed, there is only B (idler) left.|center|left]] | ||
| - | [[Image:3state.JPG|thumb|190px|'''Fig. 3 Condition 3. | + | [[Image:3state.JPG|thumb|190px|'''Fig. 3 Condition 3. Dedifferentiation of B''' <br>While after the removal of A (worker), B (idler) becomes unstable and ''dedifferentiates''.|center|left]] |
<!--Node B detects the removal of node A from the system and knows that there is only node B left.--> | <!--Node B detects the removal of node A from the system and knows that there is only node B left.--> | ||
| - | [[Image:4state.JPG|thumb| | + | [[Image:4state.JPG|thumb|210px|'''Fig. 4 Condition 4. Balanced Redifferentiation''' <br>Some Dedifferentiated cells ''redifferentiate'' into A (worker) while the others go back to B (idler). Then the system becomes stable again with the balanced ratio of A and B.|center|left]] |
<br> | <br> | ||
<!--[[Image:concepts.jpg]]--> | <!--[[Image:concepts.jpg]]--> | ||
Revision as of 18:50, 26 October 2007
Balanced Redifferentiation of E.coli !
To follow Pareto’s principle found in an ant society, our model system must satisfy the three conditions shown in Fig. 1 to 4. In our model, all individual cells have the same genetic circuits but take either of stable state A (worker) or B (idler) depending on the surrounding circumstances as if they are DIFFERENTIATE. They also change their states as if they DEDIFFERENTIATE and REDIFFERENTIATE so that the ratio of the two cell states is well balanced. (What is Pareto's principle? (Wikipedia))
As shown in Fig. 1, 2, 3, and 4, the condition of the system is changing as follows:
Bistable state ⇒ The removal of A (worker) ⇒ Dedifferentiation of B(idlers)⇒ Balanced Redifferentiation into A and of B
The system is stable when it contains both A (worker) and B (idler) "balanced" at certain ratio.
Now that A (worker) is removed, there is only B (idler) left.
While after the removal of A (worker), B (idler) becomes unstable and dedifferentiates.
Some Dedifferentiated cells redifferentiate into A (worker) while the others go back to B (idler). Then the system becomes stable again with the balanced ratio of A and B.
