Team:USTC/Tool

From 2009.igem.org

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[[Image:barcode.jpg|thumb|right|200px|Barcode & its Scanner]]
[[Image:barcode.jpg|thumb|right|200px|Barcode & its Scanner]]
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*'''Problem 1:'''
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*'''Problem 1:''' How to distinguish the different biobricks in a biobrick pool in experiment?
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How to distinguish the different biobricks in a biobrick pool in experiment?
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To take a DNA sequencing?---it's costly and time-consuming.
To take a DNA sequencing?---it's costly and time-consuming.
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We are faced with such a problem to determine the final outputs of E.ADEM (''E.coli'' Automatic Directed Evolution Machine)[https://2009.igem.org/Team:USTC/Project]. An inspiration comes from the supermarket checkout system where thousands of commodities are tagged by barcodes. This universal commercial ID both shortens the check-out time and adds the accuracy. By comparing our problem with this system, what we need to do can be concluded as to design barcodes for biobricks, '''BioBrick-Barcode''', as we call it.  
We are faced with such a problem to determine the final outputs of E.ADEM (''E.coli'' Automatic Directed Evolution Machine)[https://2009.igem.org/Team:USTC/Project]. An inspiration comes from the supermarket checkout system where thousands of commodities are tagged by barcodes. This universal commercial ID both shortens the check-out time and adds the accuracy. By comparing our problem with this system, what we need to do can be concluded as to design barcodes for biobricks, '''BioBrick-Barcode''', as we call it.  
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*'''Problem 2:'''
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*'''Problem 2:''' Where is the scanner?
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Where is the scanner?
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PCR (Polymerase Chain Reaction)[http://en.wikipedia.org/wiki/PCR], which is so conveniently conducted, can serve as the scanner while the primers it needs are the analogue of barcode sequences.
PCR (Polymerase Chain Reaction)[http://en.wikipedia.org/wiki/PCR], which is so conveniently conducted, can serve as the scanner while the primers it needs are the analogue of barcode sequences.

Revision as of 08:01, 21 October 2009

USTC
Home Team Project Modeling Parts Standard & Protocol Software Tool Human Practice Notebook

Team:USTC/Tool

Contents

Problem & Solution

Barcode & its Scanner
  • Problem 1: How to distinguish the different biobricks in a biobrick pool in experiment?

To take a DNA sequencing?---it's costly and time-consuming.

We are faced with such a problem to determine the final outputs of E.ADEM (E.coli Automatic Directed Evolution Machine)[1]. An inspiration comes from the supermarket checkout system where thousands of commodities are tagged by barcodes. This universal commercial ID both shortens the check-out time and adds the accuracy. By comparing our problem with this system, what we need to do can be concluded as to design barcodes for biobricks, BioBrick-Barcode, as we call it.

  • Problem 2: Where is the scanner?

PCR (Polymerase Chain Reaction)[http://en.wikipedia.org/wiki/PCR], which is so conveniently conducted, can serve as the scanner while the primers it needs are the analogue of barcode sequences.


Solution: To check the final outputs in the system of E.ADEM (E.coli Automatic Directed Evolution Machine), we need to design a set of DNA oligo-sequences primers as the barcodes to go through the scanner of PCR and help determining the final evolutionary products.

Design

  • A set of barcodes under a certain kind of barcode reader has to satisfy its conditions in order to be picked out respectively. For BioBrick-Barcodes, the oligo-sequences must meet several conditions as we considered:

1. Since the BioBrick-Barcodes function as PCR primers, they must satisfy the basic conditions as high-quality primers:

  a. Each primer should be 20-30 nucleotides in length; 
  b. Contain approximately equal numbers of 4 bases, with a balanced distribution of G&C residues;
  c. Hold a low propensity to form stable secondary structures;
  d. Forward and reverse primers can work properly together; 

2. As a set of barcodes, each of the primers should be perceivably different in order to be identified by the scanner:

  a. Any one of the primer cannot lead to the PCR of other DNA sequences(a plasmid with a certain target sequence.)
  b. All of the primers should be specific for the target sequence without combining with other sites. 
  • Software

Primer3[http://primer3.sourceforge.net/releases.php] is an open-source primer-design software, and we modified its C codes in parts to design the BioBrick-Barcodes. Since Primer3 is mainly used to pick primers from a DNA template while the BioBrick-Barcodes are supposed to be randomly produced, and a set of BioBrick-Barcodes should be diverse to avoid overlapping PCR, we changed three functions and structure of Primers.

  1. Add a function to randomly produce the DNA oligo-sequences which replaced the previous function used to pick 
     segments from the template.
  2. Modified the structure used to store information of each primer.
  3. Use the Libray_Mispriming to choose diverse primers.
  • Experiment

We design a set of ten diverse primers by using the modified software. Apparently, we need to conduct experiments to test its feasibility.

  1.Synthesize the DNA oligo-sequence;
  2.Construct plasmids;
  3.Conduct a 10*10 cross experiment: Each primer reacts with all the plasmids;
    

Expectation: only complementary couple leads to PCR results.

Results

cross experiment result





  • In the electrophoretogram, only the combination of primer 5 & plasmid 5, primer 6 & plasmid 6, primer 7 & plasmid 7 lead to PCR results. Along with other electrophoretograms we conclude that this set of primers can be used as a set of barcodes.



Application

  • In Synthetic Biology: BioBrick barcodes are a set of artifical DNA parts designed for PCR. They can be used alone as a high-quality PCR primer. Also, they can be used in a group as a convenient tool to identify the biobrick parts just as we do.
  • Beyond Synthetic Biology: We create a new software to design PCR primers without a template. The primers chosen from a random oligo-sequences can enlarge the application scope of PCR.