Difference between revisions of "Part:BBa K300000"

 
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<partinfo>BBa_K300000 short</partinfo>
 
<partinfo>BBa_K300000 short</partinfo>
  
BBa_K300000 is an integrative base vector backbone which can be used to integrate the desired BioBrick parts/devices/systems into the genome of ''E. coli''. This base vector can specialized to target the desired integration site in the host genome.
+
BBa_K300000 is an integrative base vector backbone which can be used to integrate the desired BioBrick parts/devices/systems into the genome of ''E. coli''. This base vector can be specialized to target the desired integration site in the host genome.
  
The default version of this backbone has the bacteriophage Phi80 attP (<partinfo>BBa_K300991</partinfo>) as integration site.
+
The default version of this backbone has the bacteriophage Phi80 attP (<partinfo>BBa_K300991</partinfo>) as integration site and an mRFP1 expression cassette (<partinfo>BBa_I763007</partinfo>) as insert.
  
This vector enables multiple integrations into the genome of the same strain.
+
This vector enables multiple integrations in different positions of the same genome.
  
 
{|align=center
 
{|align=center
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===How to propagate it before performing genome integration===
 
===How to propagate it before performing genome integration===
The default version of this vector contains the <partinfo>BBa_I52002</partinfo> insert, so it *must* be propagated in a ''ccdB''-tolerant strain such as DB3.1 (<partinfo>BBa_V1005</partinfo>).
+
This vector must be propagated in a pir+ or pir-116 strain such as BW25141 (<partinfo>BBa_K300984</partinfo>) or BW23474 (<partinfo>BBa_K300985</partinfo>) that can replicate the R6K conditional origin (<partinfo>BBa_J61001</partinfo>).
 
+
After the insertion of the desired BioBrick part in the cloning site, this vector does not contain a standard replication origin anymore, so it *must* be propagated in a pir+ or pir-116 strain such as BW25141 (<partinfo>BBa_K300984</partinfo>) or BW23474 (<partinfo>BBa_K300985</partinfo>) that can replicate the R6K conditional origin (<partinfo>BBa_J61001</partinfo>).
+
  
 +
NOTE: Another (early) version of this vector contains the <partinfo>BBa_I52002</partinfo> insert, so if you have this part it *must* be propagated in a ''ccdB''-tolerant strain such as DB3.1 (<partinfo>BBa_V1005</partinfo>). We finally decided to use the <partinfo>BBa_I763007</partinfo> instead of <partinfo>BBa_I52002</partinfo> because the latter was not stably propagated by the DB3.1 host strain. In fact, this plasmid occasionally gave unexpected bands on agarose gel in digestion screenings.
  
 
===How to engineer it===
 
===How to engineer it===
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{|align=center
 
{|align=center
|[[Image:guide.jpg|thumb|800px|center|How to engineer the integrative base vector to assemble the desired DNA ''guide''.]]
+
|[[Image:guide.jpg|thumb|800px|center|Figure 1: How to engineer the integrative base vector to assemble the desired DNA ''guide''.]]
 
|}
 
|}
  
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#Digest the integrative base vector <partinfo>BBa_K300000</partinfo> with NheI (Fig.1-c) and dephosphorylate the linearized vector to prevent re-ligation.
 
#Digest the integrative base vector <partinfo>BBa_K300000</partinfo> with NheI (Fig.1-c) and dephosphorylate the linearized vector to prevent re-ligation.
 
#Ligate the digestion products (Fig.1-d). XbaI, SpeI and NheI all have compatible protruding ends. Note that the ligation is not directional, but the ''guide'' can work in both directions.
 
#Ligate the digestion products (Fig.1-d). XbaI, SpeI and NheI all have compatible protruding ends. Note that the ligation is not directional, but the ''guide'' can work in both directions.
#Transform the ligation in a ''ccdB''-tolerant strain and screen the clone.
+
#Transform the ligation in a pir+ or pir-116 strain and screen the clone.
  
  
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{|align=center
 
{|align=center
|[[Image:passenger.jpg|thumb|800px|center|How to engineer the integrative base vector to assemble the desired DNA ''passenger''.]]
+
|[[Image:passenger.jpg|thumb|800px|center|Figure 2: How to engineer the integrative base vector to assemble the desired DNA ''passenger''.]]
 
|}
 
|}
  
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#Digest the integrative base vector <partinfo>BBa_K300000</partinfo> with EcoRI-PstI (Fig.2-c).
 
#Digest the integrative base vector <partinfo>BBa_K300000</partinfo> with EcoRI-PstI (Fig.2-c).
 
#Ligate the digestion products (Fig.2-d).
 
#Ligate the digestion products (Fig.2-d).
#Transform the ligation in a pir+/pir-116 strain. Transformants with the uncut plasmid contaminant DNA do not grow because of the ''ccdB'' toxin in <partinfo>BBa_I52002</partinfo>. Screen the clone.
+
#Transform the ligation in a pir+/pir-116 strain and screen the clone.
 
+
  
 
===How to perform genome integration===
 
===How to perform genome integration===
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Detailed protocols about attP-mediated integration can be found here:
 
Detailed protocols about attP-mediated integration can be found here:
  
*Anderson JC et al., 2010 (REFERENCE 1 [https://parts.igem.org/Part:BBa_K300000:Design#References])
+
*Anderson JC et al., 2010 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 1])
*Haldimann A and Wanner BL, 2001 (REFERENCE 8 [https://parts.igem.org/Part:BBa_K300000:Design#References])
+
*Haldimann A and Wanner BL, 2001 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 8])
  
 
Detailed protocols about homologous recombination can be found here:
 
Detailed protocols about homologous recombination can be found here:
  
*Martinez-Morales F et al., 1999 (REFERENCE 11 [https://parts.igem.org/Part:BBa_K300000:Design#References])
+
*Martinez-Morales F et al., 1999 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 11])
*Posfai G et al., 1997 (REFERENCE 12 [https://parts.igem.org/Part:BBa_K300000:Design#References])
+
*Posfai G et al., 1997 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 12])
  
 +
 +
===How to perform multiple integrations in the same genome===
 +
When this vector is integrated in the genome, the desired ''passenger'' should be maintained into the host, as well as the Chloramphenicol resistance marker and the R6K conditional replication origin. The CmR and the R6K can be excised from the genome by exploiting the two FRT recombination sites that flank them. The Flp recombinase protein mediates this recombination event, so it has to be expressed by a helper plasmid, such as pCP20 (CGSC#7629).
 +
This enables the sequential integration of several parts using the same antibiotic resistance marker, which have to be eliminated each time before the next integration step.
 +
 +
Detailed protocols about homologous recombination can be found here:
 +
*Cherepanov PP and Wackernagel W, 1995 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 3])
 +
*Datsenko KA and Wanner BL, 2000 ([https://parts.igem.org/Part:BBa_K300000:Design#References Reference 4])
  
 
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Latest revision as of 16:56, 25 January 2013

BioBrick integrative base vector for E. coli

BBa_K300000 is an integrative base vector backbone which can be used to integrate the desired BioBrick parts/devices/systems into the genome of E. coli. This base vector can be specialized to target the desired integration site in the host genome.

The default version of this backbone has the bacteriophage Phi80 attP (BBa_K300991) as integration site and an mRFP1 expression cassette (BBa_I763007) as insert.

This vector enables multiple integrations in different positions of the same genome.

BioBrick integrative base vector BBa_K300000.
Parts notation.

Glossary

The passenger is the desired DNA part to be integrated into the genome.

The guide is the DNA sequence that is used to target the passenger into a specific locus in the genome.


How to propagate it before performing genome integration

This vector must be propagated in a pir+ or pir-116 strain such as BW25141 (BBa_K300984) or BW23474 (BBa_K300985) that can replicate the R6K conditional origin (BBa_J61001).

NOTE: Another (early) version of this vector contains the BBa_I52002 insert, so if you have this part it *must* be propagated in a ccdB-tolerant strain such as DB3.1 (BBa_V1005). We finally decided to use the BBa_I763007 instead of BBa_I52002 because the latter was not stably propagated by the DB3.1 host strain. In fact, this plasmid occasionally gave unexpected bands on agarose gel in digestion screenings.

How to engineer it

The DNA guide can be changed as follows:

Figure 1: How to engineer the integrative base vector to assemble the desired DNA guide.
  1. Be sure to have the desired guide in the RFC10 standard or a compatible one (Fig.1-a).
  2. Digest the guide with XbaI-SpeI (Fig.1-b).
  3. Digest the integrative base vector BBa_K300000 with NheI (Fig.1-c) and dephosphorylate the linearized vector to prevent re-ligation.
  4. Ligate the digestion products (Fig.1-d). XbaI, SpeI and NheI all have compatible protruding ends. Note that the ligation is not directional, but the guide can work in both directions.
  5. Transform the ligation in a pir+ or pir-116 strain and screen the clone.


The DNA passenger can be changed as follows:

Figure 2: How to engineer the integrative base vector to assemble the desired DNA passenger.
  1. Be sure to have the desired passenger in the RFC10 standard or a compatible one (Fig.2-a).
  2. Digest the passenger with EcoRI-PstI (Fig.2-b).
  3. Digest the integrative base vector BBa_K300000 with EcoRI-PstI (Fig.2-c).
  4. Ligate the digestion products (Fig.2-d).
  5. Transform the ligation in a pir+/pir-116 strain and screen the clone.

How to perform genome integration

The integration into the E. coli chromosome can exploit the bacteriophage attP-mediated integration or the homologous recombination.

Detailed protocols about attP-mediated integration can be found here:

Detailed protocols about homologous recombination can be found here:


How to perform multiple integrations in the same genome

When this vector is integrated in the genome, the desired passenger should be maintained into the host, as well as the Chloramphenicol resistance marker and the R6K conditional replication origin. The CmR and the R6K can be excised from the genome by exploiting the two FRT recombination sites that flank them. The Flp recombinase protein mediates this recombination event, so it has to be expressed by a helper plasmid, such as pCP20 (CGSC#7629). This enables the sequential integration of several parts using the same antibiotic resistance marker, which have to be eliminated each time before the next integration step.

Detailed protocols about homologous recombination can be found here:

Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal XbaI site found at 169
    Illegal XbaI site found at 1539
    Illegal SpeI site found at 1727
  • 12
    INCOMPATIBLE WITH RFC[12]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.
    Illegal EcoRI site found at 2150
    Illegal NheI site found at 1558
    Illegal NheI site found at 1974
    Illegal SpeI site found at 2
    Illegal SpeI site found at 1727
    Illegal PstI site found at 16
    Illegal NotI site found at 9
    Illegal NotI site found at 2156
  • 21
    INCOMPATIBLE WITH RFC[21]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.
    Illegal EcoRI site found at 2150
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal prefix found at 2150
    Illegal suffix found at 2
    Illegal XbaI site found at 169
    Illegal XbaI site found at 1539
    Illegal SpeI site found at 1727
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal prefix found at 2150
    Plasmid lacks a suffix.
    Illegal XbaI site found at 169
    Illegal XbaI site found at 1539
    Illegal XbaI site found at 2165
    Illegal SpeI site found at 2
    Illegal SpeI site found at 1727
    Illegal PstI site found at 16
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Plasmid lacks a prefix.
    Plasmid lacks a suffix.