Davidson Missouri W/Solving the HPP in vivo

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==Developing Nodes==
==Developing Nodes==
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We represent the graph's nodes with reporter genes.  In order to allow for flipping, we must insert ''hixC'' sites within the coding regions of our reporter genes.  We call this process [[Gene splitting|''gene splitting'']].  The central issue with gene splitting is that an additional 13 amino acids are added within the resulting protein.  More often than not, we would expect these amino acids to prevent the protein from functioning.  If our reporter gene tolerates a ''hixC'' insertion, and still functions as a reporter properly, then we can use it as a node on our graph.
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We represent the graph's nodes with reporter genes.  In order to allow for flipping, we must insert ''hixC'' sites within the coding regions of our reporter genes.  We call this process [[Davidson_Missouri_W/Gene splitting|''gene splitting'']].  The central issue with gene splitting is that an additional 13 amino acids are added within the resulting protein.  More often than not, we would expect these amino acids to prevent the protein from functioning.  If our reporter gene tolerates a ''hixC'' insertion, and still functions as a reporter properly, then we can use it as a node on our graph.
==Initiating Flipping==
==Initiating Flipping==

Revision as of 21:51, 16 October 2007

Home | Background Information | Current Project: Solving the Hamiltonian Path Problem in vivo | Mathematical Modeling | Gene Splitting | Traveling Salesperson Problem | Software | Resources and Citations


Using the Hin/hixC flipping mechanism, we are developing a bacterial computer which solves a specific mathematical problem, the Hamiltonian Path problem.

Contents

The Hamiltonian Path Problem

A Hamiltonian Path is a trip through a directed graph which visits each node exactly once. A graph may have multiple Hamiltonian Paths, only one, or even none. The problem asks the following: given a graph with a designated starting point and an endpoint, does it contain a Hamiltonian path?

We solve our problem by transforming E. coli cells with specially engineered plasmids.

Designing a Plasmid

Our plasmid consists of reporter genes and hixC sites. hixC sites are placed within the coding regions of our reporter genes. The reporter genes are joined in such a way as to represent a graph. Each reporter gene represents a node, and the connection of two reporter genes together without any hixC sites in between represents an edge.

Such a plasmid design allows us to flip the edges of the graph into all possible permutations. Each permutation represents a potential path through the graph; permutations with all the proper phenotypes can be selected for. This system therefore allows for the detection of computation, as solutions to the Hamiltonian Path problem will manifest themselves via the reporter genes.

Above: A graph on a plasmid. Below: flipping into a solution.

Developing Nodes

We represent the graph's nodes with reporter genes. In order to allow for flipping, we must insert hixC sites within the coding regions of our reporter genes. We call this process gene splitting. The central issue with gene splitting is that an additional 13 amino acids are added within the resulting protein. More often than not, we would expect these amino acids to prevent the protein from functioning. If our reporter gene tolerates a hixC insertion, and still functions as a reporter properly, then we can use it as a node on our graph.

Initiating Flipping

After a plasmid has been constructed with the the reporter genes in a scrambled order, flipping can be initiated by co-transformation with a plasmid containing the Hin protein.

Detecting a Solution

The primary method for seeing if there is a solution is by screening for all correct phenotypes. For example, if some cells do not have antibiotic resistance, or if they do not exhibit a particular color, then we know they have not computed a solution to the problem. Our computer constructs are all designed to use the T7 RNA polymerase promoter. This allows us to initiate transcription as a separate event from flipping upon co-transformation with a separate vector containing the gene for the T7 RNA polymerase. Another advantage of using this promoter and polymerase is its supposed greater processivity. Larger graphs require the transcription of more genes; typically, most promoters only promote through a few. Although we have not tested more than two genes with this promoter, we expect that this system permits greater transcriptional power.

Although phenotypic screening is our primary means of verifying for solutions, there exists the possibility of a false-positive solution. In this case, all genes have their second portion immediately following their first. Yet the resulting path will be illogical: it will contain a "teleportation," which means that, in order to travel the path, it would be necessary to move between two nodes without following an edge.

File:False positive.png
An example of a false-positive solution.

The potential for false-positives thus requires another way of verifying solutions. The length of a solution, in terms of base-pairs, is always known. It is the sum of the lengths of all split genes. Furthermore, the first and last nodes are constant, as the first one is not flippable and the last node is the transcriptional terminator. These facts mean that PCR can be used to verify solutions. Primers can be designed from the first and last node, and running PCR products on a gel will give the lengths of the amplified DNA. If any segment has the correct length then we know there is a solution.

Agarose Gel with PCR Products