Synthetic Counter (iGem2005 ETH Zurich)

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(Input Module)
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* the "NOR" module, which uses these two signals to sequencially switch through the outputs 1, 2, 3 and 4.
* the "NOR" module, which uses these two signals to sequencially switch through the outputs 1, 2, 3 and 4.
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Note that all interfaces have flows described in Polymerase Per Second (PoPS), is explained in details on the [http://partsregistry.org/cgi/htdocs/AbstractionHierarchy/index.cgi abstraction hierarchy] of the MIT Registry of Parts.
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Note that all interfaces have flows described in Polymerase Per Second (PoPS), is explained in details on the [http://partsregistry.org/cgi/htdocs/AbstractionHierarchy/index.cgi abstraction hierarchy] of the MIT Registry of Parts. For instance, the input can be of any nature as long as an adequate promoter is available (e.g. heat-shock using a sigma32 promoter, IPTG using a LacI promoter, AHL using quorum sensing promoters...)
==Input Module==
==Input Module==
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The picture below puts the input module (the large box) in context, and stresses the fact that the input can be of any nature as long as an adequate promoter is available. For instance, the input signal can be a heat-shock using a sigma32 promoter, IPTG using a LacI promoter or AHL using quorum sensing promoters.
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The input module splits the input into two opposite signals. It is best described through its system boundaries. One of the outputs should be high and the other low when S is high and vice versa when S is low:
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[[Image:InputModule_SingleScheme.gif|Parts-view of Input-module]]
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The input module has 2 system boundaries. One of the outputs should be high and the other low when S is high and vice versa when S is low:
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[[Image:inputPops.png]]
[[Image:inputPops.png]]

Revision as of 07:31, 17 October 2005

Abstract. We report here the design and implementation in vivo of a gene circuit that can count up to 4. In essence, it uses two toggle switches, each storing 1 bit, to keep track of the 4 states. The design of the counter is highly modular, with the hope that it can be included as a unit in larger circuits, and also combined with further counter instances to keep track of a much larger number of states, up to (2^(n+1)) with n units. To facilitate further developments and integration to other projects, the counter is available in form of BioBricks. Among many exciting applications, the availability of a counter enables the execution of sequential instructions, and paves the way for the execution of artifical programs inside living cells.


Contents

Introduction

The past few years have seen the emergence of the field of synthetic biology, in which functional units are designed and built into cells to generate a particular behaviour, and ultimately to better understand Life's mechanisms. Previous efforts include the creation of gene circuits that generate oscillating behaviour (Elowitz00), toggle switch functionality (Atkinson03), artificial cell-cell communication (Bulter04) or pattern-forming behaviour (Basu2005). The present document describes the design and realization of a gene circuit that counts to 4.

Design of the Counter

The counter is a genetic circuit that has 1 input and 4 outputs. It uses the input signal to switch from one of the four output to the next. When the input signal is high, either output 1 or 3 is active, when it is low, output 2 or 4 is active. Thus, output 1 and 3 alternatively keep track of high input signal, while output 2 and 4 alternatively keep track of low input signals.

Overview Counter.png

As depicted above, the counter is made of two parts, serially linked:

  • the "Input" module, which splits the input into two opposite signals.
  • the "NOR" module, which uses these two signals to sequencially switch through the outputs 1, 2, 3 and 4.

Note that all interfaces have flows described in Polymerase Per Second (PoPS), is explained in details on the [http://partsregistry.org/cgi/htdocs/AbstractionHierarchy/index.cgi abstraction hierarchy] of the MIT Registry of Parts. For instance, the input can be of any nature as long as an adequate promoter is available (e.g. heat-shock using a sigma32 promoter, IPTG using a LacI promoter, AHL using quorum sensing promoters...)

Input Module

The input module splits the input into two opposite signals. It is best described through its system boundaries. One of the outputs should be high and the other low when S is high and vice versa when S is low:

InputPops.png

To achieve such behaviour, we use a unidirectional λ-system. The trigger is IPTG, which is easy to handle and debug, but does not restrict the system to other types of inputs. Since the two promoters are regulated by the same protein-operator interactions, repression and activation should be symmetrical (as very desirable proprety, see results from simulation below). Parts are available from the registry package Registry 7.05.

NOR Module

Simulation

Implementation

Results and Discussion

Applications and Perspecitves

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