Difference between revisions of "Part:BBa J31001:Design"
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− | | [[Image:Jmol_Hin_tetrad_DNA.gif|thumb| | + | | [[Image:Jmol_Hin_tetrad_DNA.gif|thumb|200px|'''Figure 1.''' 3-D structure of a Hin protein complex bound to DNA. View the [http://www.rcsb.org/pdb/explore/explore.do?structureId=1ZR4 interactive 3-D Jmol image].]] |
− | | To the left is a 3-D model of the a Hin/ DNA complex crystal structure (Protein Data Bank ID 1ZR4, Li et al. 2005). A Hin protein dimer binds each HixC sequence flanking the fragment of DNA to be inverted. The two dimers (dimer 1 = leftward green and blue protein structures; dimer 2 = rightward yellow and purple protein structures) come together to form a tetrad complex where cleaved DNA ends are swapped and ligated (Richards and Johnson 2004). | + | | To the left is a 3-D model of the a Hin/ DNA complex crystal structure (Figure 1, Protein Data Bank ID 1ZR4, Li et al. 2005). A Hin protein dimer binds each HixC sequence flanking the fragment of DNA to be inverted. The two dimers (dimer 1 = leftward green and blue protein structures; dimer 2 = rightward yellow and purple protein structures) come together to form a tetrad complex where cleaved DNA ends are swapped and ligated (Richards and Johnson 2004). |
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The Biobricks on this part are not wildtype but the cut sites are still viable. | The Biobricks on this part are not wildtype but the cut sites are still viable. | ||
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| style="width:200px" | '''Standard BioBrick Cloning Sites''' (Knight) | | style="width:200px" | '''Standard BioBrick Cloning Sites''' (Knight) | ||
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| style="width:200px" | '''BBa_J31001 Cloning Sites''' | | style="width:200px" | '''BBa_J31001 Cloning Sites''' | ||
− | | style="background:lightgrey" |<font face="courier">5'--GAATTC GCGGCCGC <font color='red'>*</font> TCTAGA <font color='blue'>*</font> --Hin coding-- <font color='purple'>*</font> ACTAGT <font color='darkgreen'>T</font> GCGGCCG<font color='magenta'>C</font>CTGCAG--</font><br><br> | + | | style="background:lightgrey" |<font face="courier">5'--GAATTC GCGGCCGC <font color='red'>*</font> TCTAGA <font color='blue'>*</font> --Hin coding-- <font color='purple'>*</font> ACTAGT <font color='darkgreen'>T</font> GCGGCCG<font color='magenta'>C</font>CTGCAG--<br>3'--CTTAAG CGCCGGCG <font color='red'>*</font> AGATCT <font color='blue'>*</font> -------------- <font color='purple'>*</font> TGATCA <font color='darkgreen'>A</font> CGCCGGC<font color='magenta'>G</font>GACGTC--</font><br><br> |
'''Prefix'''<br>There is <font color='red'>no T spacer (*)</font> between the NotI site and the XbaI site.<br>There is <font color='blue'>no G spacer (*)</font> between the XbaI and the Hin coding region.<br> | '''Prefix'''<br>There is <font color='red'>no T spacer (*)</font> between the NotI site and the XbaI site.<br>There is <font color='blue'>no G spacer (*)</font> between the XbaI and the Hin coding region.<br> | ||
− | '''Suffix'''<br>There is no <font color='purple'>T spacer</font> between the Hin coding region and the SpeI site.<br>The A spacer between the SpeI and the NotI has changed to a <font color='darkgreen'>T</font>.<br>There is an extra <font color='magenta'>C</font> between the NotI site and the PstI site | + | '''Suffix'''<br>There is no <font color='purple'>T spacer (*)</font> between the Hin coding region and the SpeI site.<br>The A spacer between the SpeI and the NotI has changed to a <font color='darkgreen'>T</font>.<br>There is an extra <font color='magenta'>C</font> between the NotI site and the PstI site |
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===Data=== | ===Data=== | ||
− | HinLVA has been assembled with a pLac promoter and RBS (see <partinfo>BBa_S03536</partinfo>) to create a HinLVA expression casette. We observe inversion of HixC-flanked segments of DNA in the presence of this casette. Inversion occurs without IPTG induction of pLac-Hin. This may be caused by read-through from the vector backbone or leaky transcription from pLac. | + | HinLVA has been assembled with a pLac promoter and RBS (see <partinfo>BBa_S03536</partinfo>) to create a HinLVA expression casette. We observe inversion of HixC-flanked segments of DNA in the presence of this casette. Inversion occurs without IPTG induction of pLac-Hin. This may be caused by Hin expression via read-through from the vector backbone or leaky transcription from pLac. |
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Revision as of 06:28, 29 October 2006
DNA invertase Hin tagged with LVA
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Hin Invertase
To the left is a 3-D model of the a Hin/ DNA complex crystal structure (Figure 1, Protein Data Bank ID 1ZR4, Li et al. 2005). A Hin protein dimer binds each HixC sequence flanking the fragment of DNA to be inverted. The two dimers (dimer 1 = leftward green and blue protein structures; dimer 2 = rightward yellow and purple protein structures) come together to form a tetrad complex where cleaved DNA ends are swapped and ligated (Richards and Johnson 2004). |
Design Notes
This part is cloned in plasmid pSB1A2.
The Biobricks on this part are not wildtype but the cut sites are still viable.
Standard BioBrick Cloning Sites (Knight) | 5'--GAATTC GCGGCCGC T TCTAGA G ----insert---- T ACTAGT A GCGGCCG CTGCAG-- 3'--CTTAAG CGCCGGCG A AGATCT C -------------- A TGATCA T CGCCGGC GACGTC-- |
BBa_J31001 Cloning Sites | 5'--GAATTC GCGGCCGC * TCTAGA * --Hin coding-- * ACTAGT T GCGGCCGCCTGCAG-- 3'--CTTAAG CGCCGGCG * AGATCT * -------------- * TGATCA A CGCCGGCGGACGTC-- Prefix |
Data
HinLVA has been assembled with a pLac promoter and RBS (see BBa_S03536) to create a HinLVA expression casette. We observe inversion of HixC-flanked segments of DNA in the presence of this casette. Inversion occurs without IPTG induction of pLac-Hin. This may be caused by Hin expression via read-through from the vector backbone or leaky transcription from pLac.
Source
Hin invertase (BBa_J31000) from Salmonella typhimurium and the LVA degredation tag (BBa_M0040).
References
- Li, W., Kamtekar, S., Xiong, Y., Sarkis, G.J., Grindley, N.D., Steitz, T.A. (2005) Structure of a synaptic gamma delta resolvase tetramer covalently linked to two cleaved DNAs. Science. 309: 1210-1215
- Sanders, E.R., Johnson, R.C. (2004) Stepwise Dissection of the Hin-catalyzed Recombination Reaction from Synapsis to Resolution. J. Mol. Biol. 340: 753–766.
- Knight, Tom. Idempotent Vector Design for Standard Assembly of Biobricks