Team:IBB Pune/protein-based-signalling

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(Difference between revisions)
(Working of the Construct)
(Working of the Construct)
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. Hence the first 0 is unable to produce any effect and the machine moves on to the next cell in the tape while remaining in state A.
. Hence the first 0 is unable to produce any effect and the machine moves on to the next cell in the tape while remaining in state A.
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The machine now encounters a 1 in this default state 'A' (represented by AHL). This results in the activation of the second module which in turn produces more of ogr. This acts like a positive feedback loop and hence state 'B' is switched on and can remain active without intervention from cassette A.
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The machine now encounters a 1 in this default state 'A' (represented by AHL). This results in the activation of the second module which in turn produces more of ogr. This acts like a positive feedback loop and hence state 'B' is switched on and can remain active without intervention from cassette 1.
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Cassette 2 also encodes for the phage lambda cI repressor protein which represses cassette 1. Thus we have a system in which the two states are mutually exclusive. In state 'B', when the machine encounters a '1', it keeps the '1' unchanged and transits to the next cell.
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Now in this state, when the machine encounters a '0' the AND gate obtains both its inputs viz. ogr and lactose which results in the production of Homoserine Lactone Synthase (enzyme producing AHL). This results in the conversion of the '0' to a '1'. Therefore this construct behaves like a unary adder as per Turing's specification.
=Problems Associated with such an Approach=
=Problems Associated with such an Approach=

Revision as of 22:16, 21 October 2009

Contents

The Complete Turing Machine

BBa K233325.JPG

The above image is a representation of the complete turing machine including inter state regulation. This model is true to Alan Turing's vision of multi-mutually exclusive states and the states being regulated by one another through outputs.

Working of the Construct

In the above construct, there are three independent modules that function

  • A constitutively working module which produces LuxR protein and LacI and Cassette 1 (encodes ogr and activates state 'B')
  • A State-'B' which is activated by State' A' and which in turn represses the working of the default state
  • An AND gate regulated activation of the turing machine function (it could be lysis, expression of a fluorescent protein or the synthesis of vanillin or methyl salicylate)

The default state of the turing machine is 'A'. In this state it encounters a '0' (represented by Lactose) first.However there are no Lactose responsive elements in either the first or the second module. The third Module which has such a module however also requires the presence of the phage protein 'ogr ' . Hence the first 0 is unable to produce any effect and the machine moves on to the next cell in the tape while remaining in state A.

The machine now encounters a 1 in this default state 'A' (represented by AHL). This results in the activation of the second module which in turn produces more of ogr. This acts like a positive feedback loop and hence state 'B' is switched on and can remain active without intervention from cassette 1.

Cassette 2 also encodes for the phage lambda cI repressor protein which represses cassette 1. Thus we have a system in which the two states are mutually exclusive. In state 'B', when the machine encounters a '1', it keeps the '1' unchanged and transits to the next cell.

Now in this state, when the machine encounters a '0' the AND gate obtains both its inputs viz. ogr and lactose which results in the production of Homoserine Lactone Synthase (enzyme producing AHL). This results in the conversion of the '0' to a '1'. Therefore this construct behaves like a unary adder as per Turing's specification.

Problems Associated with such an Approach

Modular Systems

Proof-of-concept

Relation to Project 1