Team:ETH Zurich/Modeling/Genome Static Analysis

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(Difference between revisions)
(Restriction Enzyme Analysis)
(Restriction Enzyme Analysis)
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==Restriction Enzyme Analysis==
==Restriction Enzyme Analysis==
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This section presents the computational investigation we performed in order to understand which restriction enzymes are optimal when used in our minimal genome approach, in order to find out which restriction enzymes cut the genome in fragments that most probably will lead to find the minimal genome in our reduction approach. Important is to note that this is a "statical" analysis, meaning that we do not include in the evaluation of the restriction enzyme optimality any prevision regarding to the effects its cutting patterns can have on cell physiology or cell system behaviour. We focus here only on the insights that can be obtained using three kinds of "statical" information:  
+
This section presents the computational investigation we performed in order to understand which restriction enzymes are optimal when used in our minimal genome approach, in order to find out which restriction enzymes cut the genome in fragments that most probably will lead to find the minimal genome in our reduction approach. Important is to note that this is a "statical" analysis, meaning that we do not include in the evaluation of the restriction enzyme optimality any prevision regarding to the effects its cutting patterns can have on cell physiology or cell system behaviour. We addressed questions regarding the cell system response after genome reduction using more advanced modelling techniques (a genome scale model) in the [[Team:ETH_Zurich/Modeling/Genome-Scale_Model|Genome Scale Analysis section]]. We focus here only on the insights that can be obtained using three kinds of "statical" information:  
* the genome sequence of our strain of interest (E.Coli K12 MG1655).
* the genome sequence of our strain of interest (E.Coli K12 MG1655).
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* the recognition site patterns of each of the restriction enzymes we test.
* the recognition site patterns of each of the restriction enzymes we test.
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We addressed questions regarding the cell system response after genome reduction using more advanced modelling techniques (a genome scale model) in the [[Team:ETH_Zurich/Modeling/Genome-Scale_Model|Genome Scale Analysis section]]. Nevertheless, relying only on static analysis it is possible to ask (and answer) the following questions:
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Using computational tools and the above mentioned information we are interested in asking (and answering) the following questions:
* Which are the available restriction enzymes and cutting patterns?
* Which are the available restriction enzymes and cutting patterns?
* How is the distribution of the genes in each fragment related to the frequence of cutting?
* How is the distribution of the genes in each fragment related to the frequence of cutting?
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* Is it possible to identify restriction enzymes that optimizes the probability of cutting out fragments of the genome but still keeping the cell alive (so restriction enzymes that rearely targets fragment containing essential genes)?
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* Is it possible to identify restriction enzymes that optimizes the probability of cutting out fragments of the genome but still keeping the cell alive (or better, do exist restriction enzymes that rearely targets fragment containing essential genes)?
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===Availabel restricion enzymes===
===Availabel restricion enzymes===
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[[Team:ETH_Zurich/Modeling/Genome_Static_Analysis/RestrictionTable|Table with restriction enzymes analysis]].
[[Team:ETH_Zurich/Modeling/Genome_Static_Analysis/RestrictionTable|Table with restriction enzymes analysis]].

Revision as of 15:40, 25 October 2008


Restriction Enzyme Analysis

This section presents the computational investigation we performed in order to understand which restriction enzymes are optimal when used in our minimal genome approach, in order to find out which restriction enzymes cut the genome in fragments that most probably will lead to find the minimal genome in our reduction approach. Important is to note that this is a "statical" analysis, meaning that we do not include in the evaluation of the restriction enzyme optimality any prevision regarding to the effects its cutting patterns can have on cell physiology or cell system behaviour. We addressed questions regarding the cell system response after genome reduction using more advanced modelling techniques (a genome scale model) in the Genome Scale Analysis section. We focus here only on the insights that can be obtained using three kinds of "statical" information:

  • the genome sequence of our strain of interest (E.Coli K12 MG1655).
  • the annotation information of our strain of interest (E.Coli K12 MG1655).
  • the recognition site patterns of each of the restriction enzymes we test.

Using computational tools and the above mentioned information we are interested in asking (and answering) the following questions:

  • Which are the available restriction enzymes and cutting patterns?
  • How is the distribution of the genes in each fragment related to the frequence of cutting?
  • Is it possible to identify restriction enzymes that optimizes the probability of cutting out fragments of the genome but still keeping the cell alive (or better, do exist restriction enzymes that rearely targets fragment containing essential genes)?

Availabel restricion enzymes

Table with restriction enzymes analysis.
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