Difference between revisions of "Part:BBa K404003"

 
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__NOTOC__
 
__NOTOC__
 
<partinfo>BBa_K404003 short</partinfo>
 
<partinfo>BBa_K404003 short</partinfo>
 +
{| style="color:black; margin: 20px 0px 20px 20px; float: right; text-align: justify;" cellpadding="6" cellspacing="1" border="2" align="right"
 +
! colspan="2" style="background:#66bbff;"|[AAV2]-Rep-VP123(ViralBrick-587KO-empty)_p5-TATAless
 +
|-
 +
|'''BioBrick Nr.'''
 +
|[https://parts.igem.org/Part:BBa_K404003 BBa_K404003]
 +
|-
 +
|'''RFC standard'''
 +
|[https://parts.igem.org/Help:Assembly_standard_25 RFC 25]
 +
|-
 +
|'''Requirement'''
 +
|pSB1C3<br>
 +
|-
 +
|'''Source'''
 +
|pAAV_RC from Stratagene
 +
|-
 +
|'''Submitted by'''
 +
|[http://2010.igem.org/Team:Freiburg_Bioware FreiGEM 2010]
 +
|}
  
 
<html>
 
<html>
 
<head>
 
<head>
   <title>BBa_K404003: test</title>
+
  <meta content="text/html; charset=ISO-8859-1"
 +
http-equiv="content-type">
 +
   <title></title>
 
</head>
 
</head>
 
<body>
 
<body>
 +
<title>BBa_K404003</title>
 +
<h2 style="margin-left: 0cm; text-indent: 0cm; font-weight: bold; font-size: 20px;">Brief introduction
 +
in RepVP123</h2>
 +
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 +
name="_Toc274911373"></a><a name="_Toc275742252"><span
 +
lang="EN-US">Rep proteins</span></a></h3>
 +
<p class="MsoNormal"
 +
style="margin-bottom: 0.0001pt; text-indent: 0cm;"><span
 +
style="font-size: 10pt; line-height: 200%;" lang="EN-US">&nbsp;</span></p>
 +
<p class="MsoNormal"><span lang="EN-US">The
 +
Adeno-associated virus (AAV) consists
 +
of two open reading frames (ORF), <i>rep</i> and <i>cap</i>
 +
ORF. The<i> </i>four
 +
non-structural <i>rep</i> genes are driven by two
 +
promoters located at map
 +
units 5 (</span><span lang="EN-US">p5 promoter</span><span
 +
lang="EN-US">) and 19 (</span><span lang="EN-US">p19
 +
promoter</span><span lang="EN-US">). Rep proteins
 +
are involved in
 +
genome encapsidation, regulation of gene expression and replication of
 +
the
 +
viral genome.</span></p>
 +
<p class="MsoNormal"><span lang="EN-US">The
 +
two larger proteins Rep78/68 play an
 +
essential role in viral genome integration and regulation of AAV gene
 +
expression, whereas the smaller Rep proteins are involved in viral
 +
genome
 +
encapsidation. Rep proteins act both as repressors and activators of
 +
AAV
 +
transcription in respect to the absence and presence of helper viruses
 +
such as
 +
adenoviruses (Ad) or herpes simplex viruses (HSV) by interacting with
 +
several
 +
cellular proteins </span></p>
 +
<p class="MsoNormal"><span lang="EN-US">Furthermore,
 +
in the absence of Rep
 +
proteins, as it is the case in recombinant AAVs, integration of the
 +
viral
 +
genome into the human genome is rare and random. There are several
 +
hotspots for
 +
integration of wtAAV genomes such as the human chromosome 19q13.42,
 +
known as
 +
the AAVSI site, but as well some other accessible chromatin regions for
 +
preferred integration have been found (5p13.3 and 3p24.3). Integration
 +
into the
 +
human genome is mediated by the two regulatory proteins Rep68 and Rep78
 +
driven
 +
by the AAV p5 promoter. The proteins bind to the Rep binding site (RBS)
 +
which
 +
is located within the inverted terminal repeats (ITRs). The minimal
 +
consensus
 +
Rep binding site (RBS) </span><span
 +
style="font-family: &quot;Courier New&quot;;" lang="EN-US">GAGT
 +
GAGC</span><span lang="EN-US"> is found within the
 +
ITRs and in the p5 integration-efficient
 +
element (p5IEE) of the p5 promoter </span><span lang="EN-US">(Hüser
 +
et al., 2010)</span><span lang="EN-US">. Rep78/68
 +
proteins
 +
possess DNA-binding, helicase and site-specific endonuclease activity
 +
located within
 +
the first 200 amino acids </span><span lang="EN-US">(Davis,
 +
Wu, and Owens 2000)</span><span lang="EN-US">. Since
 +
the
 +
N-terminal region is unique to the larger Rep proteins, the two smaller
 +
Rep
 +
proteins possess other biological functions. Rep52/40 gene expression
 +
is driven
 +
by the p19 promoter which is located within <i>rep</i> ORF
 +
and the proteins are
 +
involved in encapsidating the viral genome into the preformed capsids.
 +
Gene
 +
expression of these proteins is suppressed in absence of adenovirus
 +
infection by
 +
binding of Rep78/68 to the p5 promoter. Gene expression of p19 and p40
 +
is
 +
transacvtivated by the Rep proteins Rep78/68 during coinfection.</span></p>
 +
<h3 style="margin-left: 0cm; text-indent: 0cm;"><span
 +
lang="EN-US">&nbsp;</span></h3>
 +
<h3 style="margin-left: 0cm; text-indent: 0cm;"><span
 +
lang="EN-US">&nbsp;</span></h3>
 +
<h3 style="margin-left: 0cm; text-indent: 0cm; color: blue;"><span
 +
lang="EN-US" color="blue">VP proteins</span></h3>
 +
<p class="MsoNormal"><span lang="EN-US">The
 +
AAV capsid consists of 60 capsid
 +
protein subunits composed of the three cap proteins VP1, VP2, and VP3,
 +
which
 +
are encoded in an overlapping reading frame. Arranged in a
 +
stoichiometric ratio
 +
of 1:1:10, they form an icosahedral symmetry. The mRNA encoding for the
 +
cap
 +
proteins is transcribed from p40 and alternative spliced to minor and
 +
major
 +
products. Alternative splicing and translation initiation of VP2 at a
 +
nonconventional ACG initiation codon promote the expression of the VP
 +
proteins.
 +
VP1, VP2 and VP3 share a common C terminus and stop codon, but</span><span
 +
lang="EN-US"> begin with a different start codon</span><span
 +
lang="EN-US">. The N
 +
termini of VP1 and VP2 play important roles in infection and contain
 +
motifs
 +
that are highly homologous to a phospholipase A2 (PLA2) domain and
 +
nuclear
 +
localization signals (NLSs). </span><span lang="EN-US">These
 +
elements are
 +
conserved in almost all parvoviruses. </span><span
 +
lang="EN-US">(Johnson et al. 2010)</span></p>
 +
<br>
 +
<h2 style="margin-left: 0cm; text-indent: 0cm; font-weight: bold; font-size: 20px; color: black;"><a
 +
name="_Toc275817880"><span lang="EN-US" style="color: black;">Overview
 +
of RepVP123 plasmid</span></a></h2>
 
<h2 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h2 style="margin-left: 0cm; text-indent: 0cm;"><a
  name="_Toc275885921"></a><a name="_Toc275817880"><span
+
  name="_Toc275817880"><span lang="EN-US"></span></a></h2>
lang="EN-US">Overview of RepVP123 plasmid</span></a></h2>
+
<h2 style="margin-left: 0cm; text-indent: 0cm; text-align: center;"><a
 +
name="_Toc275817880"><span lang="EN-US"></span></a><img
 +
style="width: 468px; height: 160px;" alt=""
 +
src="https://static.igem.org/mediawiki/2010/8/86/Freiburg10_RepCap_HSPG-ko_p5TATAless.png"></h2>
 +
<br>
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
  name="_Toc275885922"></a><a name="_Toc275817881"><span
 
  name="_Toc275885922"></a><a name="_Toc275817881"><span
Line 29: Line 163:
 
AAV2 RepVP123, as provided e. g. in the pAAV vector from Stratagene. In
 
AAV2 RepVP123, as provided e. g. in the pAAV vector from Stratagene. In
 
order
 
order
to introduce the iGEM standard and additionally enabling the possibility to
+
to introduce the iGEM standard and additionally enabling the
 +
possibility to
 
modify
 
modify
 
the viral capsid via integration of certain motives within the viral
 
the viral capsid via integration of certain motives within the viral
Line 43: Line 178:
 
Freiburg_Bioware’s
 
Freiburg_Bioware’s
 
variant of this backbone, pSB1C3_001.</span></p>
 
variant of this backbone, pSB1C3_001.</span></p>
 +
<br>
 
<table class="MsoTableGrid"
 
<table class="MsoTableGrid"
 
  style="border: medium none ; border-collapse: collapse; width: 636px; height: 523px; text-align: left; margin-left: auto; margin-right: auto;"
 
  style="border: medium none ; border-collapse: collapse; width: 636px; height: 523px; text-align: left; margin-left: auto; margin-right: auto;"
Line 57: Line 193:
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\RepCap_complete_modifications_arrows.jpg"></p>
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\RepCap_complete_modifications_arrows.jpg"></p>
 
       <p class="MsoCaption" style="text-indent: 0cm;"><a
 
       <p class="MsoCaption" style="text-indent: 0cm;"><a
  name="_Ref275820820"><span lang="EN-US">Figure </span></a><span
+
  name="_Ref275820820"><span lang="EN-US">Figure
lang="EN-US">1</span> <span
+
1 </span></a><span
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  lang="EN-US">Mutations implemented into <i>RepVP123</i>
 
  lang="EN-US">Mutations implemented into <i>RepVP123</i>
 
in order to establish both iGEM standard and loop insertion capability.
 
in order to establish both iGEM standard and loop insertion capability.
Green arrows indicate integrated restriction sites, red red arrows
+
Green arrows indicate integrated restriction sites, red arrows
 
indicate deleted restriction sites. KpnI was deleted first and
 
indicate deleted restriction sites. KpnI was deleted first and
reinstated afterwards. (see text).</span></p>
+
reinstated later. (see text).</span></p>
 
       </td>
 
       </td>
 
     </tr>
 
     </tr>
Line 612: Line 748:
 
   </tbody>
 
   </tbody>
 
</table>
 
</table>
<p class="MsoCaption" style="text-align: left;"
+
<p class="MsoCaption" align="center"><span
align="left"><span lang="EN-US">Figure </span><span
+
  lang="EN-US">Table 1 </span> <span
  lang="EN-US">2</span> <span
+
  style="color: windowtext; font-weight: normal;" lang="EN-US">Overview
  style="color: windowtext; font-weight: normal;" lang="EN-US">Table
+
about all plasmids containing <i>RepVP123</i>
contains complete overview about all plasmids containing <i>RepVP123</i>
+
 
which
 
which
 
were used by iGEM team Freiburg_Bioware 2010.</span></p>
 
were used by iGEM team Freiburg_Bioware 2010.</span></p>
 +
<br>
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
  name="_Toc275885923"></a><a name="_Toc275817882"><span
 
  name="_Toc275885923"></a><a name="_Toc275817882"><span
Line 641: Line 777:
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Rep_synthesis_marked.jpg"></p>
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Rep_synthesis_marked.jpg"></p>
 
       <p class="MsoCaption"><a name="_Ref275818017"></a><a
 
       <p class="MsoCaption"><a name="_Ref275818017"></a><a
  name="_Ref275818042"><span lang="EN-US">Figure </span></a><span
+
  name="_Ref275818042"><span lang="EN-US">Figure 2</span></a>
lang="EN-US">3</span> <span
+
      <span
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  lang="EN-US">Restriction sites within the wild-type <i>rep</i>
 
  lang="EN-US">Restriction sites within the wild-type <i>rep</i>
Line 656: Line 792:
 
  lang="EN-US">Making
 
  lang="EN-US">Making
 
the <i>RepVP123</i>
 
the <i>RepVP123</i>
wild-type compatible with the iGEM standards required the removal of
+
wild-type construct compatible with the iGEM standards required the
 +
removal of
 
five
 
five
 
restriction sites (see </span><span lang="EN-US">Figure
 
restriction sites (see </span><span lang="EN-US">Figure
Line 673: Line 810:
 
the <i>rep</i> gene using HindIII and SwaI, which are
 
the <i>rep</i> gene using HindIII and SwaI, which are
 
single-cutting
 
single-cutting
restriction enzymes adjacent to the target area. Additionally, BamHI
+
restriction enzymes adjacent to the target area. Furthermore, BamHI
 
(859) and
 
(859) and
 
SalI (1239) were removed, because these enzymes were required for
 
SalI (1239) were removed, because these enzymes were required for
Line 688: Line 825:
 
the gene coding for the VP proteins was modified as well. The
 
the gene coding for the VP proteins was modified as well. The
 
introduction of
 
introduction of
these restriction required up to four base mutations in a row, hence it
+
these restriction required up to four base modifications in a row,
 +
hence it
 
was
 
was
 
decided to synthesize this gene fragment and replace the wild-type
 
decided to synthesize this gene fragment and replace the wild-type
Line 707: Line 845:
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Cap_synthesis_marked.jpg"></p>
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Cap_synthesis_marked.jpg"></p>
 
       <p class="MsoCaption"><span lang="EN-US">Figure
 
       <p class="MsoCaption"><span lang="EN-US">Figure
      </span><span lang="EN-US">4</span> <span
+
3 </span> <span
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  style="font-size: 8pt; color: windowtext; font-weight: normal;"
 
  lang="EN-US">Restriction sites within <i>cap</i>
 
  lang="EN-US">Restriction sites within <i>cap</i>
Line 718: Line 856:
 
   </tbody>
 
   </tbody>
 
</table>
 
</table>
 +
<br>
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 
  name="_Toc275885926"></a><a name="_Toc275817885"><span
 
  name="_Toc275885926"></a><a name="_Toc275817885"><span
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  style="text-indent: 0cm; line-height: 150%;"><span
 
  style="text-indent: 0cm; line-height: 150%;"><span
 
  lang="EN-US">To
 
  lang="EN-US">To
fulfill iGEM requirements all plasmids need to be submitted in pSB1C3,
+
fulfill iGEM requirements, all plasmids need to be submitted in pSB1C3.
therefore primers were ordered for amplifying <i>RepVP123</i>
+
Therefore, primers were ordered for amplifying <i>RepVP123</i>
 
containing all
 
containing all
modifications done so far by PCR and cloning the into pSB1C3. Still,
+
modifications done so far by PCR and cloning them into pSB1C3. Still,
 
pSB1C3
 
pSB1C3
 
contains two restriction sites for SspI and PvuII restriction enzymes
 
contains two restriction sites for SspI and PvuII restriction enzymes
Line 741: Line 880:
 
Both restriction sites interfering with ViralBrick insertions were
 
Both restriction sites interfering with ViralBrick insertions were
 
mutated to
 
mutated to
make SspI and PvuII single-cutters (see method development).</span></p>
+
make SspI and PvuII single-cutters.</span></p>
 
<table class="MsoTableGrid"
 
<table class="MsoTableGrid"
 
  style="border: medium none ; margin-left: auto; border-collapse: collapse; text-align: left; margin-right: auto;"
 
  style="border: medium none ; margin-left: auto; border-collapse: collapse; text-align: left; margin-right: auto;"
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  alt=""></p>
 
  alt=""></p>
 
       <p class="MsoCaption"><span lang="EN-US">Figure
 
       <p class="MsoCaption"><span lang="EN-US">Figure
      </span><span lang="EN-US">10</span> <span
+
4 </span><span style="color: windowtext; font-weight: normal;"
style="color: windowtext; font-weight: normal;" lang="EN-US">Comparison
+
lang="EN-US">Comparison
 
of pSB1C3 (upper row) and pSB1C3_001 (lower row). Deletions of SspI and
 
of pSB1C3 (upper row) and pSB1C3_001 (lower row). Deletions of SspI and
 
PvuII are marked by red boxes.</span></p>
 
PvuII are marked by red boxes.</span></p>
Line 772: Line 911:
 
the newly constructed pSB1C3_001. Testing this newly assembled plasmid
 
the newly constructed pSB1C3_001. Testing this newly assembled plasmid
 
in cell
 
in cell
culture revealed unexpected data. Not only did the newly assembled
+
culture revealed unexpected data: Not only did the newly assembled
 
plasmid work
 
plasmid work
(see Figure 10), but in comparison to pAAV containing the same <i>RepVP123</i>
+
(see Figure 5), but in comparison to pAAV containing the same <i>RepVP123</i>
 
construct, pSB1C3_001 showed an about 3 times higher transduction
 
construct, pSB1C3_001 showed an about 3 times higher transduction
 
efficiency.
 
efficiency.
 
Although exact reasons are still unknown, these results are probably
 
Although exact reasons are still unknown, these results are probably
 
related to
 
related to
the reduced length of pSB1C3_001 compared to the original pAAV plasmid
+
the length reduction of pSB1C3_001 compared to the original pAAV
 +
plasmid
 
of
 
of
 
approximately 1000 base pairs.</span></p>
 
approximately 1000 base pairs.</span></p>
Line 800: Line 940:
 
  src="https://static.igem.org/mediawiki/2010/2/2b/Freiburg10_pAAV_pSB1C3_001.png"></span></p>
 
  src="https://static.igem.org/mediawiki/2010/2/2b/Freiburg10_pAAV_pSB1C3_001.png"></span></p>
 
       <p class="MsoCaption"><span lang="EN-US">Figure
 
       <p class="MsoCaption"><span lang="EN-US">Figure
      </span><span lang="EN-US">11</span> <span
+
5 </span><span style="color: windowtext; font-weight: normal;"
style="color: windowtext; font-weight: normal;" lang="EN-US">AAV-293
+
lang="EN-US">AAV-293
 
cells were transfected with three plasmids pHelper,
 
cells were transfected with three plasmids pHelper,
 
pSB1C3_001_[AAV2]-Rep-VP123_p5-TATAless or pAAV_RC_IRCK and
 
pSB1C3_001_[AAV2]-Rep-VP123_p5-TATAless or pAAV_RC_IRCK and
 
pSB1C3_[AAV2]-left-ITR_pCMV_beta-globin_mVenus_hGH_[AAV2]-right-ITR
 
pSB1C3_[AAV2]-left-ITR_pCMV_beta-globin_mVenus_hGH_[AAV2]-right-ITR
 
providing essential genes and proteins for producing viral particles.
 
providing essential genes and proteins for producing viral particles.
After 48 hours post transfection, viral particles were harvested by
+
48 hours post transfection, viral particles were harvested by
 
freeze-thaw lysis and centrifugation followed by HT1080 transduction.
 
freeze-thaw lysis and centrifugation followed by HT1080 transduction.
mVenus expression of viral genomes was determined by flow cytomery
+
mVenus expression of viral genomes was determined by flow cytometry
after 24 hours post infection. </span><span
+
analysis
 +
24 hours post infection. </span><span
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">Fluorescence
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">Fluorescence
 
is measured in surviving cells.</span><span
 
is measured in surviving cells.</span><span
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">&nbsp;Results
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">&nbsp;Results
 
showed functionality of <i>RepVP123</i>
 
showed functionality of <i>RepVP123</i>
within pSB1C3_001 vector and additionally increased transduction
+
within the pSB1C3_001 vector and additionally increased transduction
 
efficiency.</span></p>
 
efficiency.</span></p>
 
       </td>
 
       </td>
Line 820: Line 961:
 
   </tbody>
 
   </tbody>
 
</table>
 
</table>
 +
<br>
 
<h4 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h4 style="margin-left: 0cm; text-indent: 0cm;"><a
 
  name="_Toc275885927"></a><a name="_Toc275817886"><span
 
  name="_Toc275885927"></a><a name="_Toc275817886"><span
Line 827: Line 969:
 
  lang="EN-US">Shutting-down
 
  lang="EN-US">Shutting-down
 
the
 
the
natural viral tropism is essential for targeting specifically tumor
+
natural viral tropism is essential for specific targeting of tumor
 
cells and
 
cells and
 
not infecting healthy cells. Therefore, the iGEM team Freiburg_Bioware
 
not infecting healthy cells. Therefore, the iGEM team Freiburg_Bioware
Line 836: Line 978:
 
knock-out was
 
knock-out was
 
cloned by designing primers containing the required base exchanges and
 
cloned by designing primers containing the required base exchanges and
performing a SDM. Like performed before, this <i>RepVP123</i>
+
performing a SDM. As before, this <i>RepVP123</i>
 
variant was tested
 
variant was tested
in cell culture as well and evaluated by flow cytometry. Results show
+
in cell culture and evaluated as well by flow cytometry. Results show
 
that
 
that
 
mutation of HSPG-binding motif has severe impact on transduction
 
mutation of HSPG-binding motif has severe impact on transduction
efficiency
+
efficiency,
 
thus enabling a viral particle carrying this knock-out and additional
 
thus enabling a viral particle carrying this knock-out and additional
 
targeting
 
targeting
motifs, e.g. within the loops or presented via N-terminal fusion to
+
motifs, e.g. within the loops or presented via N-terminal fusion, to
 
bind target
 
bind target
cells’ receptors and therefore infecting target cells at a much higher
+
cells’ receptors. Consequently, target cells are infected at a much
 +
higher
 
rate
 
rate
 
compared to unspecific infection of other cell types within an organism
 
compared to unspecific infection of other cell types within an organism
(see </span><span lang="EN-US">Figure 12</span><span
+
(see </span><span lang="EN-US">Figure 7 </span><span
 
  lang="EN-US">).</span></p>
 
  lang="EN-US">).</span></p>
 
<p class="MsoNormal" style="text-indent: 0cm;"><span
 
<p class="MsoNormal" style="text-indent: 0cm;"><span
Line 855: Line 998:
 
quantify
 
quantify
 
differences in infectivity, the infectious titer of viral particles
 
differences in infectivity, the infectious titer of viral particles
built-up of
+
made up of
 
<i>RepVP123</i> with and without HSPG binding motif was
 
<i>RepVP123</i> with and without HSPG binding motif was
 
determined by qPCR (see
 
determined by qPCR (see
</span><span lang="EN-US">Figure 14</span><span
+
</span><span lang="EN-US">Figure 8</span><span
 
  lang="EN-US">) for
 
  lang="EN-US">) for
 
different cell
 
different cell
 
lines. Results show that the implemented HSPG-knock-out verifies
 
lines. Results show that the implemented HSPG-knock-out verifies
 
results obtained
 
results obtained
from flow cytometry, infectious titers severely compared to <i>RepVP123</i>
+
from flow cytometry: Infectious titers severely dropped compared to <i>RepVP123</i>
with intact HSPG binding motif.</span></p>
+
with an intact HSPG binding motif.</span></p>
 
<table class="MsoTableGrid"
 
<table class="MsoTableGrid"
 
  style="border: medium none ; border-collapse: collapse; text-align: left; margin-left: auto; margin-right: auto;"
 
  style="border: medium none ; border-collapse: collapse; text-align: left; margin-left: auto; margin-right: auto;"
Line 874: Line 1,017:
 
       <p class="MsoNormal"
 
       <p class="MsoNormal"
 
  style="text-indent: 0cm; page-break-after: avoid;"><img
 
  style="text-indent: 0cm; page-break-after: avoid;"><img
  style="width: 595px; height: 379px;" id="Picture 2"
+
  style="width: 700px; height: 380px;" id="Picture 2"
  src="https://static.igem.org/mediawiki/2010/9/9d/Freiburg10_HSPG-ko_sequence.png"
+
  src="https://static.igem.org/mediawiki/2010/6/65/Freiburg10_HSPG-ko_redoneII.png"
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\HSPG-ko_modified.jpg"></p>
 
  alt="Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\HSPG-ko_modified.jpg"></p>
 
       <p class="MsoCaption" style="text-align: left;"
 
       <p class="MsoCaption" style="text-align: left;"
  align="left"><span lang="EN-US">Figure </span><span
+
  align="left"><span lang="EN-US">Figure 6 </span>
lang="EN-US">12</span> <span
+
      <span style="color: windowtext; font-weight: normal;"
style="color: windowtext; font-weight: normal;" lang="EN-US">Alignment
+
lang="EN-US">Alignment
of 587 loop within viral VP123: The upper sequence shows a strand
+
of 587 loop within viral VP123: The upper sequence contains the HSPG
containing the HSPG binding motif (AGA, in red boxes), the lower
+
binding motif (AGA, in red boxes), the lower
 
sequence contains the HSPG-ko introduced by the iGEM team
 
sequence contains the HSPG-ko introduced by the iGEM team
 
Freiburg_Bioware 2010 (GCT and GCC, blue boxes).</span></p>
 
Freiburg_Bioware 2010 (GCT and GCC, blue boxes).</span></p>
Line 904: Line 1,047:
 
  src="https://static.igem.org/mediawiki/2010/0/01/Freiburg10_columns_HSPG_HSPG_ko.png"></p>
 
  src="https://static.igem.org/mediawiki/2010/0/01/Freiburg10_columns_HSPG_HSPG_ko.png"></p>
 
       <p class="MsoCaption"><a name="_Ref275882130"><span
 
       <p class="MsoCaption"><a name="_Ref275882130"><span
  lang="EN-US">Figure
+
  lang="EN-US">Figure 7 </span></a>
      </span></a><span lang="EN-US">13</span>
+
 
       <span style="color: windowtext; font-weight: normal;"
 
       <span style="color: windowtext; font-weight: normal;"
 
  lang="EN-US">Transduction
 
  lang="EN-US">Transduction
Line 935: Line 1,077:
 
       <p class="MsoCaption" style="text-align: center;"
 
       <p class="MsoCaption" style="text-align: center;"
 
  align="center"><a name="_Ref275883877"><span
 
  align="center"><a name="_Ref275883877"><span
  lang="EN-US">Figure </span></a><span
+
  lang="EN-US">Figure 8 </span></a><span
lang="EN-US">14</span> <span
+
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">Infectious
 
  style="color: windowtext; font-weight: normal;" lang="EN-US">Infectious
 
titers of <i>RepVP123</i> with and without natural HSPG
 
titers of <i>RepVP123</i> with and without natural HSPG
Line 942: Line 1,083:
 
the HSPG binding motif reduces infectious titer in both HT1080 and HeLa
 
the HSPG binding motif reduces infectious titer in both HT1080 and HeLa
 
cell lines. For A431 cells, no infectious titer could be detected via
 
cell lines. For A431 cells, no infectious titer could be detected via
qPCR, which is probably related to poor transduction efficiency of A431
+
qPCR, which is probably related to the poor transduction efficiency of
 +
A431
 
cells.</span></p>
 
cells.</span></p>
 
       </td>
 
       </td>
Line 948: Line 1,090:
 
   </tbody>
 
   </tbody>
 
</table>
 
</table>
 +
<br>
 
<div class="WordSection1">
 
<div class="WordSection1">
 
<h5 style="margin-left: 0cm; text-indent: 0cm;"><a
 
<h5 style="margin-left: 0cm; text-indent: 0cm;"><a
Line 956: Line 1,099:
 
p5 promoter, the iGEM team Freiburg 2010 provides the RepCap plasmid
 
p5 promoter, the iGEM team Freiburg 2010 provides the RepCap plasmid
 
with a
 
with a
relocated p5 promoter downstream of the <i>RepCap</i>
+
relocated p5 promoter. Downstream of the <i>RepCap</i>
genes (see </span><span lang="EN-US">Figure 1</span><span
+
genes (see </span><span lang="EN-US">Figure 9 </span><span
  lang="EN-US">). Additionally the p5 promoter lacks
+
  lang="EN-US">), this p5 promoter lacks
 
the TATA box element </span><span lang="EN-US">(AVIGEN,
 
the TATA box element </span><span lang="EN-US">(AVIGEN,
 
1997)</span><b><span lang="EN-US">. </span></b><span
 
1997)</span><b><span lang="EN-US">. </span></b><span
  lang="EN-US">Those modifications result in an attenuated
+
  lang="EN-US">These modifications result in an attenuated
 
expression of the larger
 
expression of the larger
Rep proteins therefore leading to normal transcription of the Rep
+
Rep proteins leading to normal transcription of the Rep
 
proteins
 
proteins
 
driven by p19 promoter and enhanced expression of the Cap proteins,
 
driven by p19 promoter and enhanced expression of the Cap proteins,
 
which are
 
which are
under the control of the p40 promoter. Additionally, removing the p5
+
under the control of the p40 promoter. Furthermore, removing the p5
 
promoter
 
promoter
 
downstream of the <i>RepCap</i> genes and deletion of the
 
downstream of the <i>RepCap</i> genes and deletion of the
 
TATA box eliminates
 
TATA box eliminates
contamination with wtAAVs. Hence, alteration of the p5 promoter is
+
contamination with wtAAVs [Natsoulis, G., 1997]. Hence, alteration of
 +
the p5 promoter is
 
useful for
 
useful for
enhanced production of recombinant viral particles attenuating
+
enhanced production of recombinant viral particles by attenuating
 
repression of
 
repression of
 
Rep78/68 and improving gene transcription of the capsid proteins and
 
Rep78/68 and improving gene transcription of the capsid proteins and
 
Rep
 
Rep
proteins involved in genome packaging. </span></p>
+
proteins which are involved in genome packaging. </span></p>
 
<div align="center">
 
<div align="center">
 
<table class="MsoTableGrid"
 
<table class="MsoTableGrid"
Line 992: Line 1,136:
 
  src="https://static.igem.org/mediawiki/2010/0/04/Freiburg10_p5_TATA_less.png"></p>
 
  src="https://static.igem.org/mediawiki/2010/0/04/Freiburg10_p5_TATA_less.png"></p>
 
       <br>
 
       <br>
       <p class="MsoCaption" style="text-indent: 17.85pt;"><a
+
       <p class="MsoCaption" align="center"><a
  name="_Ref275919913"><span lang="EN-US">Figure </span></a><span
+
  name="_Ref275919913"><span lang="EN-US">Figure
lang="EN-US">1</span><span lang="EN-US">
+
9 </span></a><span lang="EN-US">
&nbsp;p5 TATA-less promoter is located downstream of the rep and
+
p5 TATA-less promoter located downstream of the rep and cap ORF.</span></p>
cap ORF.</span></p>
+
 
       </td>
 
       </td>
 
     </tr>
 
     </tr>
Line 1,002: Line 1,145:
 
</table>
 
</table>
 
</div>
 
</div>
<p class="MsoNormal"><span lang="EN-US">&nbsp;</span></p>
+
</div>
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
<br>
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
<br>
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
name="_Toc275885922"></a><a name="_Toc275817881"><span
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
lang="EN-US">References</span></a><br>
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
</h3>
<p class="MsoNormal"><span lang="EN-US"></span></p>
+
 
<br>
 
<br>
<p class="MsoNormal"><span lang="EN-US">References:</span></p>
 
 
<p style="margin-left: 24pt; text-indent: -24pt;"><span
 
<p style="margin-left: 24pt; text-indent: -24pt;"><span
  style="font-size: 11pt; font-family: &quot;Calibri&quot;,&quot;sans-serif&quot;;"
+
  lang="EN-US">Natsoulis, G., United States Patent 5,622,856 (1997).</span></p>
  lang="EN-US">AVIGEN,
+
<p style="margin-left: 24pt; text-indent: -24pt;"><span
I. (1997). WO9706272A3.pdf. McCracken, Thomas, P. et al.</span></p>
+
lang="EN-US">Davis, M D, J Wu, and R A Owens. 2000.
<p class="MsoNormal"><span lang="EN-US">&nbsp;</span></p>
+
Mutational analysis of
</div>
+
adeno-associated virus type 2 Rep68 protein endonuclease activity on
</body>
+
partially
</html>
+
single-stranded substrates. <i>Journal of virology</i> 74,
 +
no. 6 (March):
 +
2936-42.
 +
http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=111789&amp;tool=pmcentrez&amp;rendertype=abstract.</span></p>
 +
<p style="margin-left: 24pt; text-indent: -24pt;"><span
 +
  lang="EN-US">Hüser,
 +
Daniela, Andreas Gogol-Döring, Timo Lutter, Stefan Weger, Kerstin
 +
Winter,
 +
Eva-Maria Hammer, Toni Cathomen, Knut Reinert, and Regine Heilbronn.
 +
2010.
 +
Integration preferences of wildtype AAV-2 for consensus rep-binding
 +
sites at
 +
numerous loci in the human genome. <i>PLoS pathogens</i>
 +
6, no. 7 (January):
 +
e1000985. doi:10.1371/journal.ppat.1000985.
 +
http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2900306&amp;tool=pmcentrez&amp;rendertype=abstract.</span></p>
 +
<p style="margin-left: 24pt; text-indent: -24pt;"><span
 +
lang="EN-US">Johnson,
 +
Jarrod S, Chengwen Li, Nina DiPrimio, Marc S Weinberg, Thomas J McCown,
 +
and R
 +
Jude Samulski. 2010. Mutagenesis of adeno-associated virus type 2
 +
capsid
 +
protein VP1 uncovers new roles for basic amino acids in trafficking and
 +
cell-specific transduction. <i>Journal of virology</i> 84,
 +
no. 17 (September):
 +
8888-902. doi:10.1128/JVI.00687-10.
 +
http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2918992&amp;tool=pmcentrez&amp;rendertype=abstract.</span></p>
 +
<h2 style="margin-left: 0cm; text-indent: 0cm;"><a
 +
name="_Toc275885921"></a><a name="_Toc275817880"><span
 +
lang="EN-US"></span></a></h2>
 +
<br>
 +
<p style="margin-left: 24pt;
  
 +
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a
 +
name="_Toc275885922"></a><a name="_Toc275817881"><span
 +
lang="EN-US"></span></a><br>
 +
<h3 style="margin-left: 0cm; text-indent: 0cm;"><a name="_Toc275885922"></a><a name="_Toc275817881"><span lang="EN-US">Usage and Biology</span></a></h3>
  
 
+
<p>
 
+
This construct was used to produce viral particles in cell culture. It could be used either to produce viral particles containing only VP proteins or mosaic viruses which are an essential part for targeting and killing tumor cells. This can be achieved e.g. using <a href = "https://parts.igem.org/Part:BBa_K404163" target="blank" > BBa_K404163</a> as targeting construct and <a href = "https://parts.igem.org/Part:BBa_K404122" target="blank" > BBa_K404122</a> as gene of interest containing mGMK_TK30 which, in presence of ganciclovir is able to kill tumor cells.<br>
 
+
</p>
 
+
</html><br>
 
+
<br>
<!-- Add more about the biology of this part here
+
<br>
===Usage and Biology===
+
 
+
<!-- -->
+
 
<span class='h3bb'>Sequence and Features</span>
 
<span class='h3bb'>Sequence and Features</span>
 
<partinfo>BBa_K404003 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K404003 SequenceAndFeatures</partinfo>
 
 
<!-- Uncomment this to enable Functional Parameter display
 
===Functional Parameters===
 
<partinfo>BBa_K404003 parameters</partinfo>
 
<!-- -->
 

Latest revision as of 09:29, 30 October 2010

[AAV2]-Rep-VP123(ViralBrick-587KO-empty)_p5-TATAless

[AAV2]-Rep-VP123(ViralBrick-587KO-empty)_p5-TATAless
BioBrick Nr. BBa_K404003
RFC standard RFC 25
Requirement pSB1C3
Source pAAV_RC from Stratagene
Submitted by [http://2010.igem.org/Team:Freiburg_Bioware FreiGEM 2010]

BBa_K404003

Brief introduction in RepVP123

Rep proteins

 

The Adeno-associated virus (AAV) consists of two open reading frames (ORF), rep and cap ORF. The four non-structural rep genes are driven by two promoters located at map units 5 (p5 promoter) and 19 (p19 promoter). Rep proteins are involved in genome encapsidation, regulation of gene expression and replication of the viral genome.

The two larger proteins Rep78/68 play an essential role in viral genome integration and regulation of AAV gene expression, whereas the smaller Rep proteins are involved in viral genome encapsidation. Rep proteins act both as repressors and activators of AAV transcription in respect to the absence and presence of helper viruses such as adenoviruses (Ad) or herpes simplex viruses (HSV) by interacting with several cellular proteins

Furthermore, in the absence of Rep proteins, as it is the case in recombinant AAVs, integration of the viral genome into the human genome is rare and random. There are several hotspots for integration of wtAAV genomes such as the human chromosome 19q13.42, known as the AAVSI site, but as well some other accessible chromatin regions for preferred integration have been found (5p13.3 and 3p24.3). Integration into the human genome is mediated by the two regulatory proteins Rep68 and Rep78 driven by the AAV p5 promoter. The proteins bind to the Rep binding site (RBS) which is located within the inverted terminal repeats (ITRs). The minimal consensus Rep binding site (RBS) GAGT GAGC is found within the ITRs and in the p5 integration-efficient element (p5IEE) of the p5 promoter (Hüser et al., 2010). Rep78/68 proteins possess DNA-binding, helicase and site-specific endonuclease activity located within the first 200 amino acids (Davis, Wu, and Owens 2000). Since the N-terminal region is unique to the larger Rep proteins, the two smaller Rep proteins possess other biological functions. Rep52/40 gene expression is driven by the p19 promoter which is located within rep ORF and the proteins are involved in encapsidating the viral genome into the preformed capsids. Gene expression of these proteins is suppressed in absence of adenovirus infection by binding of Rep78/68 to the p5 promoter. Gene expression of p19 and p40 is transacvtivated by the Rep proteins Rep78/68 during coinfection.

 

 

VP proteins

The AAV capsid consists of 60 capsid protein subunits composed of the three cap proteins VP1, VP2, and VP3, which are encoded in an overlapping reading frame. Arranged in a stoichiometric ratio of 1:1:10, they form an icosahedral symmetry. The mRNA encoding for the cap proteins is transcribed from p40 and alternative spliced to minor and major products. Alternative splicing and translation initiation of VP2 at a nonconventional ACG initiation codon promote the expression of the VP proteins. VP1, VP2 and VP3 share a common C terminus and stop codon, but begin with a different start codon. The N termini of VP1 and VP2 play important roles in infection and contain motifs that are highly homologous to a phospholipase A2 (PLA2) domain and nuclear localization signals (NLSs). These elements are conserved in almost all parvoviruses. (Johnson et al. 2010)


Overview of RepVP123 plasmid


Modularization: Overview

In our terminology the term “RepVP123” encompasses the whole AAV2 genome excluding the ITRs. The rep locus comprises four proteins related to genome replication while the cap locus codes for the proteins VP1, VP2, VP3 and the assembly-associated protein (AAP), which are required for viral capsid assembly. Source of the RepVP123 BioBrick supplied within iGEM team Freiburg_Bioware 2010 Virus Construction Kit is the wild-type AAV2 RepVP123, as provided e. g. in the pAAV vector from Stratagene. In order to introduce the iGEM standard and additionally enabling the possibility to modify the viral capsid via integration of certain motives within the viral loops 453 and 587, a total of twelve mutations within RepVP123 (see Figure 1) and additionally two mutations within the pSB1C3 backbone were introduced by either Site-Directed Mutagenesis (SDM) or by ordering and cloning of specifically designed gene sequences matching the required demands. Modifying the pSB1C3 led to iGEM team Freiburg_Bioware’s variant of this backbone, pSB1C3_001.


Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\RepCap_complete_modifications_arrows.jpg

Figure 1 Mutations implemented into RepVP123 in order to establish both iGEM standard and loop insertion capability. Green arrows indicate integrated restriction sites, red arrows indicate deleted restriction sites. KpnI was deleted first and reinstated later. (see text).


 

Plasmid name:

Functionality (determinded in cell culture via transduction and flow cytometry ):

4x mutations (PstI (310), BamHI (859), SalI (1239), PstI (4073))

inserted rep fragment

inserted cap fragment

reinstated KpnI

pAAV

pSB1C3_001

HSPG-ko

pAAV_RC (wild-type)

yes

 

 

 

 

x

 

 

pAAV_RC_4x mutant

yes

x

 

 

 

x

 

 

pAAV_RC_inserts

no

x

x

x

 

x

 

 

pAAV_RC_Cap

yes

x

 

x

 

x

 

 

pAAV_RC_RepVP123

yes

x

x

x

x

x

 

 

pSB1C3_RepVP123_ p5TATAless

yes

x

x

x

x

 

x

 

pSB1C3_RepVP123_ HSPG-ko_p5TATAless

yes

x

x

x

x

 

x

x

Table 1 Overview about all plasmids containing RepVP123 which were used by iGEM team Freiburg_Bioware 2010.


Modularization: Removing iGEM restriction sites and establishing loop insertion capability

Modifications in Rep

Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Rep_synthesis_marked.jpg

Figure 2 Restriction sites within the wild-type rep gene sequence, which were removed via cloning of synthetized rep gene fragment into the plasmid. The red box indicates the region spanned by the synthetic sequence.

Making the RepVP123 wild-type construct compatible with the iGEM standards required the removal of five restriction sites (see Figure 1). This was achieved using site-directed mutagenesis for PstI (position 310) and PstI (4073). The remaining three iGEM restriction sites EcoRI (1578), PstI (1773) and EcoRI (1796) were replaced by a synthetic gene fragment, since the rep ORF contained these restriction sites in close proximity to each other plus an additional KpnI restriction site which was also not desired (see Figure 2). This gene fragment was cloned into the rep gene using HindIII and SwaI, which are single-cutting restriction enzymes adjacent to the target area. Furthermore, BamHI (859) and SalI (1239) were removed, because these enzymes were required for genetically inserting the loop modifications in VP123.

Modifications in VP123

In order to implement the restriction sites necessary for targeting via loop insertions, the gene coding for the VP proteins was modified as well. The introduction of these restriction required up to four base modifications in a row, hence it was decided to synthesize this gene fragment and replace the wild-type sequence in RepVP123 as well.

Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\Cap_synthesis_marked.jpg

Figure 3 Restriction sites within cap sequence showing introduced loop insertion restriction sites into cap to enable cloning of targeting or purification motifs into both 453 and 587 loops. Again, the red box indicates gene sequence which was synthetized.


Modularization: Adapting pSB1C3 to loop insertions – pSB1C3_001

To fulfill iGEM requirements, all plasmids need to be submitted in pSB1C3. Therefore, primers were ordered for amplifying RepVP123 containing all modifications done so far by PCR and cloning them into pSB1C3. Still, pSB1C3 contains two restriction sites for SspI and PvuII restriction enzymes in its CAT marker. Since these are necessary for cloning ViralBricks in this vector, the iGEM Team Freiburg_Bioware 2010 decided in agreement with iGEM Headquarters to implement a new standard for the pSB1C3 backbone which was named pSB1C3_001. Both restriction sites interfering with ViralBrick insertions were mutated to make SspI and PvuII single-cutters.

Figure 4 Comparison of pSB1C3 (upper row) and pSB1C3_001 (lower row). Deletions of SspI and PvuII are marked by red boxes.

RepVP123 containing both rep and cap synthetic gene fragments including the re-mutation of KpnI and the downstream p5TATA-less promotor was cloned into the newly constructed pSB1C3_001. Testing this newly assembled plasmid in cell culture revealed unexpected data: Not only did the newly assembled plasmid work (see Figure 5), but in comparison to pAAV containing the same RepVP123 construct, pSB1C3_001 showed an about 3 times higher transduction efficiency. Although exact reasons are still unknown, these results are probably related to the length reduction of pSB1C3_001 compared to the original pAAV plasmid of approximately 1000 base pairs.

 

Figure 5 AAV-293 cells were transfected with three plasmids pHelper, pSB1C3_001_[AAV2]-Rep-VP123_p5-TATAless or pAAV_RC_IRCK and pSB1C3_[AAV2]-left-ITR_pCMV_beta-globin_mVenus_hGH_[AAV2]-right-ITR providing essential genes and proteins for producing viral particles. 48 hours post transfection, viral particles were harvested by freeze-thaw lysis and centrifugation followed by HT1080 transduction. mVenus expression of viral genomes was determined by flow cytometry analysis 24 hours post infection. Fluorescence is measured in surviving cells. Results showed functionality of RepVP123 within the pSB1C3_001 vector and additionally increased transduction efficiency.


Turning-off natural tropism: HSPG-knock-out

Shutting-down the natural viral tropism is essential for specific targeting of tumor cells and not infecting healthy cells. Therefore, the iGEM team Freiburg_Bioware 2010 decided to knock-out the viral natural tropism delivered by the heperan sulfate proteoglycan-(HSPG) binding site within the viruses 587 loop. The knock-out was cloned by designing primers containing the required base exchanges and performing a SDM. As before, this RepVP123 variant was tested in cell culture and evaluated as well by flow cytometry. Results show that mutation of HSPG-binding motif has severe impact on transduction efficiency, thus enabling a viral particle carrying this knock-out and additional targeting motifs, e.g. within the loops or presented via N-terminal fusion, to bind target cells’ receptors. Consequently, target cells are infected at a much higher rate compared to unspecific infection of other cell types within an organism (see Figure 7 ).

To quantify differences in infectivity, the infectious titer of viral particles made up of RepVP123 with and without HSPG binding motif was determined by qPCR (see Figure 8) for different cell lines. Results show that the implemented HSPG-knock-out verifies results obtained from flow cytometry: Infectious titers severely dropped compared to RepVP123 with an intact HSPG binding motif.

Description: \\132.230.232.133\x\users\FreiGem\iGEM2010\Stefan\Pictures_Results\HSPG-ko_modified.jpg

Figure 6 Alignment of 587 loop within viral VP123: The upper sequence contains the HSPG binding motif (AGA, in red boxes), the lower sequence contains the HSPG-ko introduced by the iGEM team Freiburg_Bioware 2010 (GCT and GCC, blue boxes).

 

Figure 7 Transduction efficiency of HT1080 cells measured by flow cytometry. Fluorescence is measured in surviving cells. Knock-out of HSPG binding motif greatly reduces transduction efficiency compared to RepVP123 containing the motiv.

 

Figure 8 Infectious titers of RepVP123 with and without natural HSPG binding motif tested in different cell lines via qPCR. Shutting-down the HSPG binding motif reduces infectious titer in both HT1080 and HeLa cell lines. For A431 cells, no infectious titer could be detected via qPCR, which is probably related to the poor transduction efficiency of A431 cells.


p5 TATA-less promoter

In contrast to the natural location of the p5 promoter, the iGEM team Freiburg 2010 provides the RepCap plasmid with a relocated p5 promoter. Downstream of the RepCap genes (see Figure 9 ), this p5 promoter lacks the TATA box element (AVIGEN, 1997). These modifications result in an attenuated expression of the larger Rep proteins leading to normal transcription of the Rep proteins driven by p19 promoter and enhanced expression of the Cap proteins, which are under the control of the p40 promoter. Furthermore, removing the p5 promoter downstream of the RepCap genes and deletion of the TATA box eliminates contamination with wtAAVs [Natsoulis, G., 1997]. Hence, alteration of the p5 promoter is useful for enhanced production of recombinant viral particles by attenuating repression of Rep78/68 and improving gene transcription of the capsid proteins and Rep proteins which are involved in genome packaging.


Figure 9 p5 TATA-less promoter located downstream of the rep and cap ORF.



References


Natsoulis, G., United States Patent 5,622,856 (1997).

Davis, M D, J Wu, and R A Owens. 2000. Mutational analysis of adeno-associated virus type 2 Rep68 protein endonuclease activity on partially single-stranded substrates. Journal of virology 74, no. 6 (March): 2936-42. http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=111789&tool=pmcentrez&rendertype=abstract.

Hüser, Daniela, Andreas Gogol-Döring, Timo Lutter, Stefan Weger, Kerstin Winter, Eva-Maria Hammer, Toni Cathomen, Knut Reinert, and Regine Heilbronn. 2010. Integration preferences of wildtype AAV-2 for consensus rep-binding sites at numerous loci in the human genome. PLoS pathogens 6, no. 7 (January): e1000985. doi:10.1371/journal.ppat.1000985. http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2900306&tool=pmcentrez&rendertype=abstract.

Johnson, Jarrod S, Chengwen Li, Nina DiPrimio, Marc S Weinberg, Thomas J McCown, and R Jude Samulski. 2010. Mutagenesis of adeno-associated virus type 2 capsid protein VP1 uncovers new roles for basic amino acids in trafficking and cell-specific transduction. Journal of virology 84, no. 17 (September): 8888-902. doi:10.1128/JVI.00687-10. http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2918992&tool=pmcentrez&rendertype=abstract.



Usage and Biology

This construct was used to produce viral particles in cell culture. It could be used either to produce viral particles containing only VP proteins or mosaic viruses which are an essential part for targeting and killing tumor cells. This can be achieved e.g. using BBa_K404163 as targeting construct and BBa_K404122 as gene of interest containing mGMK_TK30 which, in presence of ganciclovir is able to kill tumor cells.




Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 3611
    Illegal XhoI site found at 1913
    Illegal XhoI site found at 2099
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 4137
    Illegal BsaI site found at 4319
    Illegal BsaI site found at 4356
    Illegal SapI site found at 3048