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Team:Edinburgh/Cellulases (C model)
From 2011.igem.org
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(→Syn: a simple demonstration of synergy) |
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* The world is a 2D grid. | * The world is a 2D grid. | ||
** Each spot in the grid can contain a '''sugar''', a '''bond''' between sugars, or '''nothing'''. | ** Each spot in the grid can contain a '''sugar''', a '''bond''' between sugars, or '''nothing'''. | ||
| - | * Cellulose is modelled as alternating sugars and bonds: s-b-s-b-s-b-s-b-s-b-s etc etc. | + | * Cellulose is modelled as alternating sugars and bonds: ''s-b-s-b-s-b-s-b-s-b-s'' etc etc. |
* There are three enzyme types: endoglucanase, exoglucanase, and β-glucosidase. | * There are three enzyme types: endoglucanase, exoglucanase, and β-glucosidase. | ||
** The enzymes move about randomly, in a "brownian motion" manner. | ** The enzymes move about randomly, in a "brownian motion" manner. | ||
** If an enzyme is on the same space as a bond, it can cut it: | ** If an enzyme is on the same space as a bond, it can cut it: | ||
*** Endoglucanase can only cut bonds away from the ends of a chain. | *** Endoglucanase can only cut bonds away from the ends of a chain. | ||
| - | *** Exoglucanase can only cut bonds if this results in a cellobiose molecule (s-b-s) forming. | + | *** Exoglucanase can only cut bonds if this results in a cellobiose molecule (''s-b-s'') forming. |
*** β-glucosidase can only cut cellobiose bonds. | *** β-glucosidase can only cut cellobiose bonds. | ||
* There is inhibition of exoglucanase by cellobiose; it does not cut bonds if there is a nearby cellobiose molecule. | * There is inhibition of exoglucanase by cellobiose; it does not cut bonds if there is a nearby cellobiose molecule. | ||
Revision as of 20:42, 20 August 2011
How does this whole synergy thing even work? It can seem almost magical that having enzymes closer together can increase their usefulness, but consider the following statements about cellulose degradation, all of which are true:
- Exoglucanase chews away at the end of a cellulase chain, producing cellobiose sugars.
- Endoglucanase cuts cellulose chains in the middle, essentially turning one chain into two.
- Cellobiose inhibits the action of the above enzymes.
- β-glucosidase cuts cellobiose in half, producing two glucose molecules.
Facts 1 and 2 mean that exoglucanase works best with endoglucanase nearby, since every time endoglucanase acts, it produces new chain-ends for exoglucanase to attack. Meanwhile, facts 1, 3, and 4 mean that β-glucosidase helps nearby copies of the other enzymes by preventing the cellobiose from inhibiting them.
Syn: a simple demonstration of synergy
We can demonstrate that there is (potentially) a huge difference between the synergistic and non-synergistic systems with Edinburgh's Syn C program. This is a 2D simulation that works in the following way:
- The world is a 2D grid.
- Each spot in the grid can contain a sugar, a bond between sugars, or nothing.
- Cellulose is modelled as alternating sugars and bonds: s-b-s-b-s-b-s-b-s-b-s etc etc.
- There are three enzyme types: endoglucanase, exoglucanase, and β-glucosidase.
- The enzymes move about randomly, in a "brownian motion" manner.
- If an enzyme is on the same space as a bond, it can cut it:
- Endoglucanase can only cut bonds away from the ends of a chain.
- Exoglucanase can only cut bonds if this results in a cellobiose molecule (s-b-s) forming.
- β-glucosidase can only cut cellobiose bonds.
- There is inhibition of exoglucanase by cellobiose; it does not cut bonds if there is a nearby cellobiose molecule.
Simulating synergy / non-synergy
We can run two different simulations with the same settings. However, in one simulation the enzymes float about freely, whereas in the other they travel in triplets, each triplet containing one of each type of enzyme, side by side.
Conclusion
Synergy - it works!
