Difference between revisions of "Part:BBa K1321300"

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[[File:IC14 Different plasmids isolated from KI strains.jpg|900px|thumb|left|'''Figure 1. Confirmation of pSEVA321, pSEVA331, pSEVA351, pBla-Vhb-122 and pBAV1K ability to replicate in ''G.xylinus.''. pSEVA331 can replicate in ''G.xylinus''. ''G.xylinus'' igem strain was transformed with pSEVA321-Bb using electroporation. Transformed cells were plated out on HS-Cam plates. Single colonies were then picked and grown in 5ml HS-cellulose medium (in 50ml Corning tubes) at 180rpm, 30C for 3 days. Cultures were then miniprepped using Qiagen DNA mini kit (see protocol here)". Miniprepped DNA was then used as template for pSEVA-specific primers. PCR products were visualized using 1% agarose gel, 100V, 20min. Ladder - NEB 2logL, expected band size for positive control - 328bp; size of lowest bright band of the ladder-500bp.''' ]]
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[[File:IC14 Different plasmids isolated from KI strains.jpg|900px|thumb|left|'''Figure 1. Confirmation of pSEVA321, pSEVA331, pSEVA351, pBla-Vhb-122 and pBAV1K ability to replicate in ''K. rhaeticus''. pSEVA331 can replicate in ''K. rhaeticus''. ''K. rhaeitucs'' iGEM strain was transformed with pSEVA321-Bb using electroporation. Transformed cells were plated out on HS-Cam plates. Single colonies were then picked and grown in 5ml HS-cellulose medium (in 50ml Corning tubes) at 180rpm, 30C for 3 days. Cultures were then miniprepped using Qiagen DNA mini kit (see protocol here)". Miniprepped DNA was then used as template for pSEVA-specific primers. PCR products were visualized using 1% agarose gel, 100V, 20min. Ladder - NEB 2logL, expected band size for positive control - 328bp; size of lowest bright band of the ladder-500bp.''' ]]
  
  
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''Komagataeibacter'' toolkit was designed to ease genetic engineering of cellulose-based biomaterials using the cellulose synthesizing bacterium ''Komagataeibacter rhaeticus iGEM'' (parts Bba_K1321305 and BBa_K1321306). As no registry parts had been tested in ''K. rhaeticus'', the aim of this toolkit was to determine the parts usable in ''K. rhaeticus'' and to characterize them in this host. pSEVA331-Bb is a non-standard broad host range plasmid capable of replication in ''K. rhaeticus'' and ''E. coli'' (a shuttle vector) and was selected because the registry's standard plasmid backbone pSB1C3 can not be used for ''K. rhaeticus'' engineering.
 
''Komagataeibacter'' toolkit was designed to ease genetic engineering of cellulose-based biomaterials using the cellulose synthesizing bacterium ''Komagataeibacter rhaeticus iGEM'' (parts Bba_K1321305 and BBa_K1321306). As no registry parts had been tested in ''K. rhaeticus'', the aim of this toolkit was to determine the parts usable in ''K. rhaeticus'' and to characterize them in this host. pSEVA331-Bb is a non-standard broad host range plasmid capable of replication in ''K. rhaeticus'' and ''E. coli'' (a shuttle vector) and was selected because the registry's standard plasmid backbone pSB1C3 can not be used for ''K. rhaeticus'' engineering.
  
NOTE: Because the registry's standard plasmid backbone pSB1C3 is not capable of replication in ''Komagataeibacter or Gluconacetobacter'' species, the ''Komagataeibacter'' genetic engineering toolkit is housed mainly in pSEVA331-Bb. pSEVA331-Bb is a non-standard backbone, which therefore can't be quality controlled by and maintained in the Registry. However, in order to make the ''Komagataeibacter'' toolkit available for the synthetic biology community, Imperial iGEM 2014 team has made it freely available in AddGene or upon request, with quality control provided (see Experience).  
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NOTE: Because the registry's standard plasmid backbone pSB1C3 is not capable of replication in ''Komagataeibacter or Gluconacetobacter'' species, the ''Komagataeibacter'' genetic engineering toolkit is housed mainly in pSEVA331-Bb. pSEVA331-Bb is a non-standard backbone, which therefore can't be quality controlled by and maintained in the Registry. However, in order to make the ''Komagataeibacter'' toolkit available for the synthetic biology community, Imperial iGEM 2014 team has made it freely available in AddGene or upon request.  
  
 
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Revision as of 15:47, 6 May 2016

pSEVA331-Bb - pSEVA331 with biobrick prefix and suffix

This is pSEVA331 converted into a biobrick compatible format by substituting the original multiple cloning site for biobrick prefix and suffix. pSEVA331 is a broad host range plasmid, capable of replication in E.coli and several other organisms. It is capable of replication in the cellulose producing bacteria Komagataeibacter rhaeticus and Gluconacetobacter xylinum. We have used it as our standard backbone for Komagataeibacter genetic engineering, in the Komagataeibacter toolkit (parts BBa_K1321295 - BBa_K1321332).


Figure 1. Confirmation of pSEVA321, pSEVA331, pSEVA351, pBla-Vhb-122 and pBAV1K ability to replicate in K. rhaeticus. pSEVA331 can replicate in K. rhaeticus. K. rhaeitucs iGEM strain was transformed with pSEVA321-Bb using electroporation. Transformed cells were plated out on HS-Cam plates. Single colonies were then picked and grown in 5ml HS-cellulose medium (in 50ml Corning tubes) at 180rpm, 30C for 3 days. Cultures were then miniprepped using Qiagen DNA mini kit (see protocol here)". Miniprepped DNA was then used as template for pSEVA-specific primers. PCR products were visualized using 1% agarose gel, 100V, 20min. Ladder - NEB 2logL, expected band size for positive control - 328bp; size of lowest bright band of the ladder-500bp.












'


Komagataeibacter toolkit was designed to ease genetic engineering of cellulose-based biomaterials using the cellulose synthesizing bacterium Komagataeibacter rhaeticus iGEM (parts Bba_K1321305 and BBa_K1321306). As no registry parts had been tested in K. rhaeticus, the aim of this toolkit was to determine the parts usable in K. rhaeticus and to characterize them in this host. pSEVA331-Bb is a non-standard broad host range plasmid capable of replication in K. rhaeticus and E. coli (a shuttle vector) and was selected because the registry's standard plasmid backbone pSB1C3 can not be used for K. rhaeticus engineering.

NOTE: Because the registry's standard plasmid backbone pSB1C3 is not capable of replication in Komagataeibacter or Gluconacetobacter species, the Komagataeibacter genetic engineering toolkit is housed mainly in pSEVA331-Bb. pSEVA331-Bb is a non-standard backbone, which therefore can't be quality controlled by and maintained in the Registry. However, in order to make the Komagataeibacter toolkit available for the synthetic biology community, Imperial iGEM 2014 team has made it freely available in AddGene or upon request.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.
    Illegal EcoRI site found at 2872
    Illegal SpeI site found at 2
    Illegal PstI site found at 16
    Illegal NotI site found at 9
    Illegal NotI site found at 2878
  • 21
    INCOMPATIBLE WITH RFC[21]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.
    Illegal EcoRI site found at 2872
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal prefix found at 2872
    Illegal suffix found at 2
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal prefix found at 2872
    Plasmid lacks a suffix.
    Illegal XbaI site found at 2887
    Illegal SpeI site found at 2
    Illegal PstI site found at 16
    Illegal NgoMIV site found at 1191
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.