Team:Slovenia/Biobrick

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=Improved BioBrick Standard=
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<font size="6" color="#009ee0"><b>BioBRICKS</b></font>
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The goal of our project was to investigate and demonstrate the feasibility of polypeptide assembly based on modular nanoBricks. Potentials of this approach are vast (see Discussion and Vision) and for the development of applications it is essential to have available a large collection of “nuts and bolts” to assemble polypeptide nanostructures. We produced all together more than 100 BioBricks, which comprise a significant number of different natural as well as designed coiled-coil forming segments as well as different polypeptide oligomerization domains. In addition we prepared several “functional polypeptides”, which provide additional useful features to the material, such as different biological activities (antimicrobial peptide, growth factors, cell attachment motifs…), optical properties, enzymatic activity...
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On the other hand we extended the BioBrick standard by introducing sites that allow extension of peptide linker sequences. Length of the linkers between polypeptide domains is crucial to determine the accessible geometry of the assembly, and our extended standard provides a tool to extend the length of a linker by any required length in increments of two residues. This task, particularly concerning small extensions would otherwise require the preparation of a new domain construct.
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<center> <img src="https://static.igem.org/mediawiki/2009/c/c0/Bio1.GIF" align="center" width="550" height="344" border="0" />
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For a multitude reasons we would like to work with the upgrade of 2007 Freiburg iGEM proposed standard (Assembly standard 25).  The upgrade includes altered multiple-cloning site which enables friendly scar after part ligation and simple extension of linker between parts.
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For further information see:
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=====Advantages:=====
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*in-frame fusion of protein parts
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*benign protein scar/scars
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*preserving standard restriction sites of prefix and suffix
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*four new restriction sites are added in multiple-cloning site
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<li><a href="https://2009.igem.org/Team:Slovenia/Linker-extension_standard.html" class="plavo">Linker-extension standard</a><br /></li>
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*heat inactivation??
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<li><a href="https://2009.igem.org/Team:Slovenia/nanoBRICKs.html" class="plavo">nanoBRICKs PRO</a><br /></li>
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*no Dam methylation problem for XbaI
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*stand-alone protein expression
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<li><a href="https://2009.igem.org/Deposited_BioBricks.html" class="plavo">Deposited BioBRICKS</a><br /></li>
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*full BBb compatibility and
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*blunt-cutting isochizomer of NgoMIV (NaeI) and XmaI (SmaI) possibility of directional cloning with two
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<li><a href="https://2009.igem.org/Favourite_Parts.html" class="plavo">Favourite Parts</a><br /></li>
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restriction enzymes enables part transfer between different formats and other potentially interesting transfer reactions
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=====Disadvantages:=====
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*unexpected site effects for users not aware of different prefix/suffix
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*N-parts could be assembled with different enzyme combination
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*not compatible to BioFusion format (frame shift; stop codon)
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*not compatible to BBb format (Berkeley format)
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*additional limitations on the nucleotide sequence to avoid additional restriction sites
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Here we describe sequence properties of modified vector BioBrick-NIC-II. All sequences defined herein are specified in the 5' to 3' direction.
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===A: BioBrick-NIC-II originates from standard Biobrick vector===
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The difference is in multiple cloning sites.
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The main reasons for changing multiple cloning sites are:
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#Defined position of promoter and terminator from coding sequence coded with part or parts, which ensures efficient transcription and translation of protein; and
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#Additional sequences linked to parts, which could be exploited when linker is needed between combined parts.
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Although most promoters and RBS and tags and terminators are currently specified as separate parts in the Registry, we will use a new design in which these elements are included within the vector, as we plan to prepare and isolate many proteins and this design will also decrease the number of required cloning steps and will be suesull for others desiring to prepare recombinant proteins in E.coli. We expect the new design will reduce the likelihood of unexpected functional composition problems between promoter / terminator and coding sequence.
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The BioBrick-NIC-II vector is especially appropriate for cloning and combining parts coding short peptides.
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The current assembly process requires certain sequence properties for the part and the surrounding DNA.
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''prefix: 5' gaattc(EcoRI) gcggccgc(NotI) promoter (invariant region) tctaga(XbaI) gccggc(NgoMIV) accggt(AgeI)''
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''suffix: 5' cccggg(XmaI) tccgga(BspEI) terminator (invariant region) gcggccg(NotI) ctgcag(PstI)''
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===B: Multiple-cloning site===
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[[Image:MCSjpg.JPG]]
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Three types of multiple cloning sites were constructed. First, between NotI site and XbaI sites of multiple cloning site of standard Biobrick vector a T7 promoter and ATG (star codon) with or without His-tag were inserted. Between SpeI and NotI sites a TAA (stop codon) and T7 terminator with or without His-tag were inserted. Between XbaI and SpeI site NgoMIV, AgeI, XmaI and BspEI sites were inserted. To simplify selection of positive clones containing ligated parts a CcdB domain was inserted between AgeI and XmaI sites.
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#MCS-I: N-His
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gaattc(EcoRI) gcggccgc(NotI) T7-promoter-RBS-ATG Tyr-His-tag tctaga(XbaI) gccggc(NgoMIV) accggt(AgeI) ccdB-domain cccggg(XmaI) tccgga(BspEI) actagt(SpeI) STOP-T7-terminator gcggccg(NotI) ctgcag(PstI)
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#MCS-II: NC
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gaattc(EcoRI) gcggccgc(NotI) T7-promoter-RBS-ATG tctaga(XbaI) gccggc(NgoMIV) accggt(AgeI) ccdB-domain cccggg(XmaI) tccgga(BspEI) actagt(SpeI) STOP-T7-terminator gcggccg(NotI) ctgcag(PstI)
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#MCS-III: C-His
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gaattc(EcoRI) gcggccgc(NotI) T7-promoter-RBS-ATG tctaga(XbaI) gccggc(NgoMIV) accggt(AgeI) ccdB-domain cccggg(XmaI) tccgga(BspEI) actagt(SpeI) Tyr-His-tag STOP-T7-terminator gcggccg(NotI) ctgcag(PstI)
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T7-promoter-RBS-ATG: taatacgactcactataggggaattgtgagcggataacaattcccctGtagaaataattttgtttaactttaaga aggaggtaaata ATG
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Tyr-His-tag: TAT catcaccatcaccatcac
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STOP-T7-terminator: TAA ctagcataaccccttggggcctctaaacgggGctagaggggttttttg
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===C: Restrictions===
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Allowed sequences within BioBrick-NIC-II parts include any DNA sequence which does not contain the following subsequences:
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GAATTC recognized by EcoRI restriction enzyme;
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CTGCAG recognized by PstI restriction enzyme;
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GCGGCCGC recognized by NotI restriction enzyme;
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ACTAGT recognized by SpeI restriction enzyme;
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TCTAGA recognized by XbaI restriction enzyme;
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GCCGGC recognized by NgoMIV restriction enzyme;
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TCCGGA recognized by BspEI restriction enzyme;
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CCCGGG recognized by XmaI restriction enzyme;
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ACCGGT recognized by AgeI restriction enzyme.
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===D: Cloning===
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#BioBrick-NIC-II Suffix: Each BioBrick-NIC-II part must contain precisely this sequence immediately following the 3' end of the part: TCCGGA ACTAGT (note: if constructing a primer, this sequence must be reverse complemented.)
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#BioBrick-NIC-II Suffix: Each BioBrick-NIC-II part must contain precisely the following sequence immediately 5' of the part: TCTAGA GCCGGC
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Part could be cloned into multiple cloning sites of BioBrick-NIC-II vector on four different ways:
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1. Into XbaI and SpeI restriction site of multiple cloning sites.
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2. Into NgoMIV and BspEI restriction site of multiple cloning sites.
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3. Into NgoMIV and XmaI restriction site of multiple cloning sites. With this ligation two additional amino acids, Ser and Gly, are added on C terminal site of part.
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4. Into AgeI and BspEI restriction site of multiple cloning sites. With this ligation two additional amino acids, Thr and Gly, are added on N terminal site of part.
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[[Image:cloningjpg.JPG]]
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===E: Assembly Scars===
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#With using XbaI PstI and EcoRI SpeI restriction sites for combining two parts a scar coding for D and R is formed.
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#With using NgoMI PstI and EcoRI BspEI restriction sites for combining two parts a scar coding for Ser and Gly is formed.
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[[Image:scars.JPG]]
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===F: Compatibility===
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Each part suited for cloning into standard Biobrick vector could be cloned also into vector BioBrick-NIC-II and vice versa. The part suitable for standard Biobrick vector could be cloned into BioBrick-NIC-II vector into XbaI, SpeI restriction sites in multiple cloning site.
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===G: Plasmid context===
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BioBrick-NIC-II vector is composed from similar elements (antibiotic resistance, origin of replication, ccdB domain) as standard Biobrick vectors with the exception of multiple cloning site.  
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===H: Sequencing===
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Sequencing primers are identical as sequencing primers for standard Biobrick vectors and are:
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VF2: TGCCACCTGACGTCTAAGAA;
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VR: ATTACCGCCTTTGAGTGAGC.
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===I: Strains===
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The BioBrick-NIC-II vector and parts cloned into BioBrick-NIC-II vector could be cloned into the bacterial K-12 cloning strain (endA-). We recommend strains such as Top10, DH10B, and DH5a.
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Latest revision as of 02:48, 22 October 2009



BioBRICKS


The goal of our project was to investigate and demonstrate the feasibility of polypeptide assembly based on modular nanoBricks. Potentials of this approach are vast (see Discussion and Vision) and for the development of applications it is essential to have available a large collection of “nuts and bolts” to assemble polypeptide nanostructures. We produced all together more than 100 BioBricks, which comprise a significant number of different natural as well as designed coiled-coil forming segments as well as different polypeptide oligomerization domains. In addition we prepared several “functional polypeptides”, which provide additional useful features to the material, such as different biological activities (antimicrobial peptide, growth factors, cell attachment motifs…), optical properties, enzymatic activity...

On the other hand we extended the BioBrick standard by introducing sites that allow extension of peptide linker sequences. Length of the linkers between polypeptide domains is crucial to determine the accessible geometry of the assembly, and our extended standard provides a tool to extend the length of a linker by any required length in increments of two residues. This task, particularly concerning small extensions would otherwise require the preparation of a new domain construct.





For further information see:



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