Team:Johns Hopkins-BAG/A New Standard

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==Someething==
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=Building Blocks: Large DNA/Genome assembly made easy!=
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tRNA genes have been as a documented source of genome instability in Saccharomyces cerevisiae v. 1.0. As a measure to combat genome instability, as well as examine the effects of a more rigidly constrained genome, the tRNA genes for Sc 2.0 are being relocated to a specialized chromosome, the tRNA array. This entirely synthetic chromosome thus far only consists of the tRNA genes from chromosomes III and IX of S. cerevisiae. The tRNA array of chromosomes III and IX of S. cerevisiae 2.0 consists of 17 tRNA genes; each gene consists of the coding region of the tRNA From S. cerevisiae and the upstream and downstream flanking regions from a close relative of S. cerevisiae, Ashbya gossypii. Use of the fusion tRNA genes was required to avoid incorporating the repetitive sequences often found upstream of tRNAs in S. cerevisiae, as another aspect of our redesign philosophy for Sc 2.0 is to minimize nonessential repetitive DNA. Each of the genes is a representation of the same gene found on chromosome III and IX with all duplicates removed. Between each tRNA gene is a rox recombination site that will allow for subsequent induced recombination within and limited to the tRNA chromosome, when the Dre recombinase is expressed at the whim of the investigator, so that the importance of order and relative copy numbers of tRNA genes on the tRNA array chromosome can be examined. Also it will be possible to detect deletions and more complex rearrangements of genes using this system and their phenotypic effect.
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==Overview==
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The Johns Hopkins University Build a Genome team has proposed a new standard, [[Media:RFC_38_-_Building_Blocks_-_Standard_Large_DNA_Genome_Construction.pdf|RFC 38]], for the construction and assembly of large DNA. The physical assembly of standard parts is currently a non-standard process, which can either come from direct genome PCR with restriction enzyme sites incorporated into the PCR primers, or overlap assembly PCR. Furthermore, current Biobrick construction standards [RFC10, RFC11,RFC12 etc.] rely heavily on restriction enzyme based methods, which can be sequence, cost and time restrictive. This is especially true of large DNA assembly, where 100% control of over DNA sequence may be mandatory, such as in whole genome assembly. We propose a novel standard, The Building Block Method, for both the construction of standard parts and their assembly
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This Building Block standard can be either:
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*Interchangeable
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*Non-interchangeable format, based on the desired use of the part.
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==What is a Building Block?==
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*A Standard Build Block is a ~750 base pair sequence of DNA that is composed of annotated biological parts. This particular size represents a “sweet spot” for a currently optimized set of efficient assembly techniques (e.g. high accuracy sequencing in a single run) but need not be fixed in stone. The Building Block, however, may not be composed entirely of single biological parts (as in BioBricks) and the junction with neighboring Building Blocks may be essential for biological for function.
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*A Composite Building Block is composed of two or more Building Blocks. Composite Building Blocks may be constructed from non-interchangeable Building Blocks or interchangeable Building Blocks.
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==Standard Assembly==
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Building blocks are assembled using (Uracil Specific Excision Reagent) USER reaction assembly, which relies on a uracil base within the end of the Building Block DNA. Both 5’ ends of Building blocks must conform to the extremely degenerate consensus sequence of A{Nx}T in which x= 3,5,7,9 or 11. There are no other sequence requirements. The general format for a building block can be seen in Figure 1.
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*Non-interchangeable Building blocks MAY have unique and different sequences for the {Nx} region. These sequences MAY be part of the Building Block functional contents
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*Interchangeable Building blocks MUST have A{Nx}T sequences that conform to a standard sequence agreed to by the community of researchers that decide to use it.
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[[Image:BuildingBlock.jpg|600px|thumb|center|Standard Building Block Diagram]]
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Here the Building block is diagrammed to conform to the sequence 5’ A{Nx}U … A{Nx}T3’. Building blocks can be synthesized either in this format (by including terminal oligonucleotides each containing a single strategically placed deoxyuracil residue) or the more conventional 5’ A{Nx}T … A{Nx}T 3’, in which the terminal oligonucleotides are composed of the four normal DNA bases.  Either set of primers can be used to amplify a Building Block, depending on the stage in the synthesis procedure.
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==Interchangability==
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*An Interchangeable Building Block contains standard sequences on both 3’ and 5’ends
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*A non-interchangeable Building Block MAY contain non-standard 3’ or  5’ ends to aid in the construction of Composite Building Blocks.
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[[Image:BBstandardseq.jpg|600px|thumb|center|Interchangeable Building Block Standard Ends]]
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Latest revision as of 13:41, 15 October 2009

Contents

Building Blocks: Large DNA/Genome assembly made easy!

Overview

The Johns Hopkins University Build a Genome team has proposed a new standard, RFC 38, for the construction and assembly of large DNA. The physical assembly of standard parts is currently a non-standard process, which can either come from direct genome PCR with restriction enzyme sites incorporated into the PCR primers, or overlap assembly PCR. Furthermore, current Biobrick construction standards [RFC10, RFC11,RFC12 etc.] rely heavily on restriction enzyme based methods, which can be sequence, cost and time restrictive. This is especially true of large DNA assembly, where 100% control of over DNA sequence may be mandatory, such as in whole genome assembly. We propose a novel standard, The Building Block Method, for both the construction of standard parts and their assembly

This Building Block standard can be either:

  • Interchangeable
  • Non-interchangeable format, based on the desired use of the part.

What is a Building Block?

  • A Standard Build Block is a ~750 base pair sequence of DNA that is composed of annotated biological parts. This particular size represents a “sweet spot” for a currently optimized set of efficient assembly techniques (e.g. high accuracy sequencing in a single run) but need not be fixed in stone. The Building Block, however, may not be composed entirely of single biological parts (as in BioBricks) and the junction with neighboring Building Blocks may be essential for biological for function.
  • A Composite Building Block is composed of two or more Building Blocks. Composite Building Blocks may be constructed from non-interchangeable Building Blocks or interchangeable Building Blocks.

Standard Assembly

Building blocks are assembled using (Uracil Specific Excision Reagent) USER reaction assembly, which relies on a uracil base within the end of the Building Block DNA. Both 5’ ends of Building blocks must conform to the extremely degenerate consensus sequence of A{Nx}T in which x= 3,5,7,9 or 11. There are no other sequence requirements. The general format for a building block can be seen in Figure 1.

  • Non-interchangeable Building blocks MAY have unique and different sequences for the {Nx} region. These sequences MAY be part of the Building Block functional contents
  • Interchangeable Building blocks MUST have A{Nx}T sequences that conform to a standard sequence agreed to by the community of researchers that decide to use it.
Standard Building Block Diagram

Here the Building block is diagrammed to conform to the sequence 5’ A{Nx}U … A{Nx}T3’. Building blocks can be synthesized either in this format (by including terminal oligonucleotides each containing a single strategically placed deoxyuracil residue) or the more conventional 5’ A{Nx}T … A{Nx}T 3’, in which the terminal oligonucleotides are composed of the four normal DNA bases. Either set of primers can be used to amplify a Building Block, depending on the stage in the synthesis procedure.

Interchangability

  • An Interchangeable Building Block contains standard sequences on both 3’ and 5’ends
  • A non-interchangeable Building Block MAY contain non-standard 3’ or 5’ ends to aid in the construction of Composite Building Blocks.


Interchangeable Building Block Standard Ends