Team:Aberdeen Scotland/Parts/ 2002

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<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2001">Bba_K1352001</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2001">Bba_K1352001</a></li>
<li class="curr"><a class="curr" href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2002">Bba_K1352002</a></li>
<li class="curr"><a class="curr" href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2002">Bba_K1352002</a></li>
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<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2003">Bba_K1352003</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2004">Bba_K1352004</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2004">Bba_K1352004</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2006">Bba_K1352006</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Parts/_2006">Bba_K1352006</a></li>
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<u>In-fusion primers used</u><br><br>
<u>In-fusion primers used</u><br><br>
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Removal of β-hairpin 1 (GCTGCAACCGTTACCGGCATAAACCGCCTGGGAGCATTCTCTGTTGTGGAG)<br>
Removal of β-hairpin 1 (GCTGCAACCGTTACCGGCATAAACCGCCTGGGAGCATTCTCTGTTGTGGAG)<br>
Primer A: ATTATCAGCTTTACCCGTACTGGTAACCAGTGCGCCG <br>
Primer A: ATTATCAGCTTTACCCGTACTGGTAACCAGTGCGCCG <br>
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Primer 1: GGTAAAGCTGATAATGTCGTACTGGAAAATGGCGGAC  <br>
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Primer 1: GGTAAAGCTGATAATGTCGTACTGGAAAATGGCGGAC  <br><br>
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<br><br>
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Removal of β-hairpin 2 (GGTGCCGCTGTCAGTGGTACCCGGAGCGACGGAAAGGCATTCAGTATCGGA) <br>
Removal of β-hairpin 2 (GGTGCCGCTGTCAGTGGTACCCGGAGCGACGGAAAGGCATTCAGTATCGGA) <br>
Primer 2: GGAATCGGCCAGCAGTACACCGC <br>
Primer 2: GGAATCGGCCAGCAGTACACCGC <br>
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<center>
<center>
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<img src="img src="https://static.igem.org/mediawiki/parts/e/ec/Beta_4.png"><br>
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<img src="https://static.igem.org/mediawiki/parts/e/ec/Beta_4.png"><br>
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<font size="2">Fig.4&nbsp;&nbsp;&nbsp;&nbsp;KpnI cut site within Ag43 coding sequence.<br>
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<font size="2">Fig.4&nbsp;&nbsp;&nbsp;&nbsp;KpnI cut site within Ag43 coding sequence.<br></font></center>
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Source: Kjærgaard et. al., 2000; Van der Woude & Henderson, 2008 (modified).</font></center>
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<center>
<center>
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<img src="img src="https://static.igem.org/mediawiki/parts/a/a2/Beta_5.png"><br>
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<img src="https://static.igem.org/mediawiki/parts/a/a2/Beta_5.png"><br>
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<font size="2">Fig.5&nbsp;&nbsp;&nbsp;&nbsp;XbaI+KpnI digest of Bba_K1352001 (A) and Bba_K1352002 (B).<br>
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<font size="2">Fig.5&nbsp;&nbsp;&nbsp;&nbsp;XbaI+KpnI digest of Bba_K1352001 (A) and Bba_K1352002 (B).<br></font></center>
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Source: Kjærgaard et. al., 2000; Van der Woude & Henderson, 2008 (modified).</font></center>
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<br>
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<br><br>
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<p>Bba_K1352001 was used as a control. Since it contains β-hairpin sequences, two prominent bands corresponding to 2.5 kb and 4.1 kb are present confirming presence of one XbaI and one KpnI cut sites. Clone with removed β-hairpins yield a single band, which corresponds to plasmid linearization by XbaI (6.5 kb); KpnI did not cut the plasmid, which suggests that β-hairpin 2 was removed. <br><br> In addition, a range of single and double restriction digests was carried out in order to ensure that no major indels occurred in the process of In-Fusion and created BioBrick behaves as expected and yields desired band pattern.</p>
<p>Bba_K1352001 was used as a control. Since it contains β-hairpin sequences, two prominent bands corresponding to 2.5 kb and 4.1 kb are present confirming presence of one XbaI and one KpnI cut sites. Clone with removed β-hairpins yield a single band, which corresponds to plasmid linearization by XbaI (6.5 kb); KpnI did not cut the plasmid, which suggests that β-hairpin 2 was removed. <br><br> In addition, a range of single and double restriction digests was carried out in order to ensure that no major indels occurred in the process of In-Fusion and created BioBrick behaves as expected and yields desired band pattern.</p>
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<br>
 
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<br>
 
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<img src="https://static.igem.org/mediawiki/parts/3/35/Beta_6.png"><br>
 
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Fig. 6 Diagnostic restriction digest panel.<br><br>
 
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<p>Single digests with EcoRI, XbaI, SpeI, PstI, BglII and HindIII cause a single cut within the vector and therefore result in plasmid linearization. As expected, in all cases a single band at 6.5 kB position is visible, which corresponds to the full size of a vector. </p><br>
 
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<p>EcoRI+PstI and XbaI+SpeI result in the release of a BioBrick construct from a vector yielding two fragments of 4.5kb+2kb and 4.4kb+2.1 kb respectively.</p><br>
 
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<p>Double digests with BglII+SpeI and HindIII+XbaI were carried out in order to confirm the presence of FLAG+MCS.</p><br><br>
 
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<img src="https://static.igem.org/mediawiki/parts/8/8d/Table_1.png"><br><br>
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<center>
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<img src="https://static.igem.org/mediawiki/parts/3/35/Beta_6.png">
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<br>
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<font size="2">Fig.6&nbsp;&nbsp;&nbsp;&nbsp;Diagnostic restriction digest panel.
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<br>
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</font>
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</center>
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<br>
 +
 
 +
 
 +
 
 +
<p>Single digests with EcoRI, XbaI, SpeI, PstI, BglII and HindIII cause a single cut within the vector and therefore result in plasmid linearization. As expected, in all cases a single band at 6.5 kB position is visible, which corresponds to the full size of a vector. </p>
 +
<p>EcoRI+PstI and XbaI+SpeI result in the release of a BioBrick construct from a vector yielding two fragments of 4.5kb+2kb and 4.4kb+2.1 kb respectively.</p>
 +
<p>Double digests with BglII+SpeI and HindIII+XbaI were carried out in order to confirm the presence of FLAG+MCS.</p>
 +
 
 +
<img src="https://static.igem.org/mediawiki/parts/8/8d/Table_1.png"><br><br><br>
<i>b) Confirming BioBrick Bba_K1352002 construction using DNA sequencing</i><br>
<i>b) Confirming BioBrick Bba_K1352002 construction using DNA sequencing</i><br>
<p>Our Ag43+FLAG+MCS(-)β-hairpins was sequenced by the DNA Sequencing & Services Unit, Dundee University. </p>
<p>Our Ag43+FLAG+MCS(-)β-hairpins was sequenced by the DNA Sequencing & Services Unit, Dundee University. </p>
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<img src="https://static.igem.org/mediawiki/parts/1/1f/Table_2.png"><br><br>
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<center><img src="https://static.igem.org/mediawiki/parts/1/1f/Table_2.png"><br></center>
<p> Sequencing primers spaced approximately every 600 bp were used to ensure good coverage. Fragments were combined together using Clustal Omega and yield a high confidence reading along the entire sequence. It confirmed the absence of two β-hairpins at expected locations; open reading frame remained unaffected. Our construct sequence was identical to that of the protein product of Bba_K1352001, with the exception of the protein sequence encoded in the β-hairpins. </p>
<p> Sequencing primers spaced approximately every 600 bp were used to ensure good coverage. Fragments were combined together using Clustal Omega and yield a high confidence reading along the entire sequence. It confirmed the absence of two β-hairpins at expected locations; open reading frame remained unaffected. Our construct sequence was identical to that of the protein product of Bba_K1352001, with the exception of the protein sequence encoded in the β-hairpins. </p>
<br><br>
<br><br>
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<img src="https://static.igem.org/mediawiki/parts/c/cd/Beta_11.png"><br><br>
 
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Fig. 7 Confirmation of the removal of β-hairpin 1. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 1 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 1 clearly visible.<br><br>
 
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<img src="https://static.igem.org/mediawiki/parts/0/08/Beta_12.png"><br><br>
 
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Fig. 8 Confirmation of the removal of β-hairpin 2. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 2 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 2 clearly visible. <br><br>
 
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<img src="table"><br><br>
 
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Fig. 9 Translation of: Query - Bba_K1352001; Subject - Bba_K1352002. Translation of β-hairpin sequences indicated in yellow.<br><br>
 
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<h3>7.    Testing the physiology and function of Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002)</h3><br><br>
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<i>a) Testing the aggregation properties of Ag43+FLAG+MCS</i><br><br>
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<center>
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<p>Overnight cultures of Ag43+FLAG+MCS, Ag43+FLAG+MCS(-)β-hairpins and Ag43 were transferred onto sterile glass test tubes, induced with 0.2% arabinose and incubated in a shaking water bath at 37oC for >2hrs. Subsequently, test tubes were removed from the water bath and photographed for visual investigation for aggregation.</p><br><br>
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<img src="https://static.igem.org/mediawiki/parts/c/cd/Beta_11.png">
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<img src="table"><br><br>
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<br>
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Fig. 10 Aggregation after induction with 0.2% arabinose of A) Ag43 without FLAG (Bba_K1352000); B) Ag43+FLAG+MCS (Bba_K1352001); Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002).<br><br>
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<font size="2">Fig.7&nbsp;&nbsp;&nbsp;&nbsp;Confirmation of the removal of β-hairpin 1. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 1 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 1 clearly visible.
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<p>A clear difference is visible between aggregation levels of tested BioBricks. Ag43 clearly aggregates when induced with arabinose. Suprisingly, Ag43+FLAG+MCS does not display aggregation properties, even though it possesses β-hairpin sequences. We hypothesize that insertion of foreign peptide sequences, in this case FLAG tag epitope, slightly changes the shape of Ag43 at places critical for clumping and disrupts velcro-like mechanism of aggregation. Ag43+FLAG+MCS(-)β-hairpins also does not display any aggregation properties. Although we cannot confirm that this is due to removal of β-hairpin sequences and not presence of a FLAG tag epitope sequence due to lack of Ag43(-)FLAG(-)β-hairpins, literature evidence provided evidence that the lack of aggregation properties is due to removal of β-hairpins and would persist if FLAG+MCS were removed (Heras et. al., 2014).</p><br><br>
+
<br>
-
<p>Since the lack of aggregation properties in Bba_K1352001 may be foreign peptide sequence specific, created BioBrick Bba_K1352002 which lacks β-hairpins is still a useful construct which can be utilized in a range of projects where aggregation is undesirable. </p><br><br>
+
</font>
 +
</center>
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<br><br>
 +
 
 +
 
 +
 
 +
<center>
 +
<img src="https://static.igem.org/mediawiki/parts/0/08/Beta_12.png">
 +
<br>
 +
<font size="2">Fig.8&nbsp;&nbsp;&nbsp;&nbsp;Confirmation of the removal of β-hairpin 2. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 2 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 2 clearly visible.
 +
<br>
 +
</font>
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</center>
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<br><br>
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 +
 
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<center>
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<img src="https://static.igem.org/mediawiki/parts/4/49/Beta_9.png">
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<br>
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<font size="2">Fig.9&nbsp;&nbsp;&nbsp;&nbsp;Translation of: Query - Bba_K1352001; Subject - Bba_K1352002. Translation of β-hairpin sequences indicated in yellow.
 +
<br>
 +
</font>
 +
</center>
 +
<br><br>
 +
 
 +
 
 +
 
 +
 
 +
<h3>7.    Testing the physiology and function of Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002)</h3><br>
 +
<i>a) Testing the aggregation properties of Ag43+FLAG+MCS</i><br>
 +
<p>Overnight cultures of Ag43+FLAG+MCS, Ag43+FLAG+MCS(-)β-hairpins and Ag43 were transferred onto sterile glass test tubes, induced with 0.2% arabinose and incubated in a shaking water bath at 37oC for >2hrs. Subsequently, test tubes were removed from the water bath and photographed for visual investigation for aggregation.</p>
 +
 
 +
 
 +
 
 +
<center>
 +
<img src="https://static.igem.org/mediawiki/parts/c/cc/Beta_10.png">
 +
<br>
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<font size="2">Fig.10&nbsp;&nbsp;&nbsp;&nbsp;Aggregation after induction with 0.2% arabinose of A) Ag43 without FLAG (Bba_K1352000); B) Ag43+FLAG+MCS (Bba_K1352001); Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002).
 +
<br>
 +
</font>
 +
</center>
 +
 
 +
 
 +
 
 +
 
 +
<p>A clear difference is visible between aggregation levels of tested BioBricks. Ag43 clearly aggregates when induced with arabinose. Suprisingly, Ag43+FLAG+MCS does not display aggregation properties, even though it possesses β-hairpin sequences. We hypothesize that insertion of foreign peptide sequences, in this case FLAG tag epitope, slightly changes the shape of Ag43 at places critical for clumping and disrupts velcro-like mechanism of aggregation. Ag43+FLAG+MCS(-)β-hairpins also does not display any aggregation properties. Although we cannot confirm that this is due to removal of β-hairpin sequences and not presence of a FLAG tag epitope sequence due to lack of Ag43(-)FLAG(-)β-hairpins, literature evidence provided evidence that the lack of aggregation properties is due to removal of β-hairpins and would persist if FLAG+MCS were removed (Heras et. al., 2014).</p>
 +
<p>Since the lack of aggregation properties in Bba_K1352001 may be foreign peptide sequence specific, created BioBrick Bba_K1352002 which lacks β-hairpins is still a useful construct which can be utilized in a range of projects where aggregation is undesirable. </p>
<p>Note: Further characterization is needed in order to determine whether removal of β-hairpin sequences does not interfere with foreign peptides expression on cell surface membrane.</p><br><br>
<p>Note: Further characterization is needed in order to determine whether removal of β-hairpin sequences does not interfere with foreign peptides expression on cell surface membrane.</p><br><br>
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<h3>References</h3>
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<h3>References</h3><br>
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1)     Heras, B., Totsika, M., Peters, K. M., Paxman, J. J., Gee, C. L., Jarrott, R. J., & Schembri, M. A. (2014). The antigen 43 structure reveals a molecular Velcro-like mechanism of autotransporter-mediated bacterial clumping. Proceedings of the National Academy of Sciences, 111(1), 457-462.
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1)&nbsp;&nbsp;&nbsp;&nbsp;Heras, B., Totsika, M., Peters, K. M., Paxman, J. J., Gee, C. L., Jarrott, R. J., & Schembri, M. A. (2014). The antigen 43 structure reveals a molecular Velcro-like mechanism of autotransporter-mediated bacterial clumping. Proceedings of the National Academy of Sciences, 111(1), 457-462.<br>
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2)     Kjærgaard, K., Schembri, M. A., Hasman, H., & Klemm, P. (2000). Antigen 43 from Escherichia coli induces inter-and intraspecies cell aggregation and changes in colony morphology of Pseudomonas fluorescens. Journal of bacteriology, 182(17), 4789-4796.
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2)&nbsp;&nbsp;&nbsp;&nbsp;Kjærgaard, K., Schembri, M. A., Hasman, H., & Klemm, P. (2000). Antigen 43 from Escherichia coli induces inter-and intraspecies cell aggregation and changes in colony morphology of Pseudomonas fluorescens. Journal of bacteriology, 182(17), 4789-4796.<br>
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3)     Kjærgaard, K., Hasman, H., Schembri, M. A., & Klemm, P. (2002). Antigen 43-mediated autotransporter display, a versatile bacterial cell surface presentation system. Journal of bacteriology, 184(15), 4197-4204.
+
3)&nbsp;&nbsp;&nbsp;&nbsp;Kjærgaard, K., Hasman, H., Schembri, M. A., & Klemm, P. (2002). Antigen 43-mediated autotransporter display, a versatile bacterial cell surface presentation system. Journal of bacteriology, 184(15), 4197-4204.<br>
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4)     Van der Woude, M. W., & Henderson, I. R. (2008). Regulation and function of Ag43 (flu). Annu. Rev. Microbiol., 62, 153-169.
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4)&nbsp;&nbsp;&nbsp;&nbsp;Van der Woude, M. W., & Henderson, I. R. (2008). Regulation and function of Ag43 (flu). Annu. Rev. Microbiol., 62, 153-169.<br>
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Latest revision as of 02:09, 18 October 2014

Team:Aberdeen Scotland/Parts - 2014.ogem.org




Ag43+FLAG+MCS(-)β-hairpins

Abstract

We describe the creation of Biobrick constrct Bba_K1352002 which expresses autotransporter Ag43 with an inserted FLAG epitope tag at codon 148, flanked by multiple cloning restriction sites. Two 17 amino acids long beta hairpins were removed from Ag43 in order to eliminate native aggregation properties. We describe the design and construction of the new Biobrick, and its verification using restriction digestion and DNA sequencing. We show that removal of β-hairpins removes auto-aggregation capability of Ag43, creating a useful reagent that can be used for E. coli surface display.

1. Structure and function

Antigen 43 (sometimes called Ag43 or fluffing protein) is a phase-variable outer membrane protein encoded by flu gene. It is native to E.coli K12 strain and is usually expressed at about 50, 000 copies/cell. Ag34 precursor is 1039 amino acids long and subsequently becomes cleaved into alpha and beta chains (499 and 488 amino acids long respectively). The beta subunit forms a β-barrel pore via which alpha-subunit translocates to the cell surface, and with which it remains non-covalently joined. The surface alpha chain can be released by a brief heat treatment at approx. 60oC. Ag43 is an autotransporter protein, therefore it possesses all information necessary for translocation to the cell surface in its coding sequence. Ag43 mediates autoaggregation, via a velcro-like mechanism (Heras et. al., 2014), and plays a role in E.coli biofilm formation. Interestingly, the alpha subunit is able to express foreign peptide sequences on E.coli cell surface if inserted just in front of codon 148 (Kjærgaard et. al., 2002).


Fig.1    Graphic representation of Ag43 autotransporter structure and process of autotransportation.
Source: Kjærgaard et. al., 2000; Van der Woude & Henderson, 2008 (modified).


2. Rationale for beta-hairpins removal

The shape of α-subunit of Ag43 resembles letter L (Fig.2). It consists of a 'β-helix domain [which forms] the stem of the letter L, followed by three rungs flanked by four β-hairpin motifs that bend the protein by about 110° and a C-terminal (...) parallel β-helix domain [which forms] the bottom of the letter L' (Heras et. al., 2014). It has been indicated that this unique shape plays a crucial role in cell-to-cell aggregation via velcro-like mechanism, in which α-subunits form a dimer by coling around each other. This interaction is strengthened by Van der Waals interactions, hydrogen bonds and salt bridges facilitated by the L-shape (Heras et. al., 2014). Recent research demonstrates that disruption of the bend and straightening of the shape by removal of two β-hairpin sequences eliminates self-association of Ag43 proteins (Heras et. al., 2014). Removal of β-hairpins does not interfere with protein translocation to the cell surface membrane.


Hairpin 1 sequence           268    AATVTGTNRLGAFSVVA    284
Hairpin 2 sequence           341    GAAVSGTRSDGKAFSIG    357



Fig.2    A) Graphic representation of Ag43 alpha-subunit; B) Interaction between two alpha-subunits in a velcro-like mechanism of auto-aggregation; C) Disruption of L-shape and linearization of the alpha-subunit eliminates auto-aggregation.
Source: Heras et. al., 2014 (modified)


3. Biobrick description and potential uses

BioBrick Bba_K1352002 is a modified version of the Bba_K1352001 BioBrick. It is composed of an Ag43 coding sequence with an in-frame FLAG epitope tag flanked by BglII and HindIII multiple cloning sites inserted within the alpha-subunit in front of codon 148 of Ag43. Two β-hairpin forming sequences were removed from the Ag43 coding sequence, maintaining ORF. Expression of Ag43 is under the control of the pBAD promoter; it includes a ribosome binding site as well as two transcriptional terminators.

Structure of the BioBrick was designed to allow easy insertion of foreign protein sequences of choice at codon 148 with a simple restriction digest with BglII and HindIII followed by ligation in cases where aggregation is undesirable.

Potential uses of this BioBrick include surface display of foreign peptide sequences and synthetic vaccines production.

4. Template for foreign peptide insertion


Depending on the length, desired foreign peptide sequence can be purchased as oligos or a synthetic piece of DNA. In order to keep the foreign protein sequence in-frame, a following template should be used:

5' gct gtg AGA TCT (your sequence) AAG CTT aac acc 3' [mote reading frame of Ag43 is indicated by nucleotide triplets]

BglII recognition site; HindIII recognition site; sequence adjacent to foreign peptide insertion site


5. Making of the Biobrick and plasmid modularization


Bba_K1352001 BioBrick (Ag43+FLAG+MCS) was a starting material for this construct. Two β-hairpins were removed via In-Fusion reaction (Clonetech). For more information regarding the construction of this BioBrick please see: https://2014.igem.org/Team:Aberdeen_Scotland/Parts


Fig.3    Plasmid map of Bba_K1352001 BioBrick. Position of β-hairpins indicated.



In-fusion primers used

Removal of β-hairpin 1 (GCTGCAACCGTTACCGGCATAAACCGCCTGGGAGCATTCTCTGTTGTGGAG)
Primer A: ATTATCAGCTTTACCCGTACTGGTAACCAGTGCGCCG
Primer 1: GGTAAAGCTGATAATGTCGTACTGGAAAATGGCGGAC

Removal of β-hairpin 2 (GGTGCCGCTGTCAGTGGTACCCGGAGCGACGGAAAGGCATTCAGTATCGGA)
Primer 2: GGAATCGGCCAGCAGTACACCGC
Primer B: CTGCTGGCCGATTCCGGCGGTCAGGCGGATGC


6. Construct testing - molecular biology aspect


a) Diagnostic restriction digests

A double digest with XbaI and KpnI was performed in order to screen for clones lacking β-hairpin sequences. KpnI is a unique cutter, which recognizes G_GTAC^C sequence. It cuts uniquely within the β-hairpin 2 sequence.


Fig.4    KpnI cut site within Ag43 coding sequence.


Fig.5    XbaI+KpnI digest of Bba_K1352001 (A) and Bba_K1352002 (B).

Bba_K1352001 was used as a control. Since it contains β-hairpin sequences, two prominent bands corresponding to 2.5 kb and 4.1 kb are present confirming presence of one XbaI and one KpnI cut sites. Clone with removed β-hairpins yield a single band, which corresponds to plasmid linearization by XbaI (6.5 kb); KpnI did not cut the plasmid, which suggests that β-hairpin 2 was removed.

In addition, a range of single and double restriction digests was carried out in order to ensure that no major indels occurred in the process of In-Fusion and created BioBrick behaves as expected and yields desired band pattern.


Fig.6    Diagnostic restriction digest panel.

Single digests with EcoRI, XbaI, SpeI, PstI, BglII and HindIII cause a single cut within the vector and therefore result in plasmid linearization. As expected, in all cases a single band at 6.5 kB position is visible, which corresponds to the full size of a vector.

EcoRI+PstI and XbaI+SpeI result in the release of a BioBrick construct from a vector yielding two fragments of 4.5kb+2kb and 4.4kb+2.1 kb respectively.

Double digests with BglII+SpeI and HindIII+XbaI were carried out in order to confirm the presence of FLAG+MCS.




b) Confirming BioBrick Bba_K1352002 construction using DNA sequencing

Our Ag43+FLAG+MCS(-)β-hairpins was sequenced by the DNA Sequencing & Services Unit, Dundee University.


Sequencing primers spaced approximately every 600 bp were used to ensure good coverage. Fragments were combined together using Clustal Omega and yield a high confidence reading along the entire sequence. It confirmed the absence of two β-hairpins at expected locations; open reading frame remained unaffected. Our construct sequence was identical to that of the protein product of Bba_K1352001, with the exception of the protein sequence encoded in the β-hairpins.




Fig.7    Confirmation of the removal of β-hairpin 1. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 1 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 1 clearly visible.



Fig.8    Confirmation of the removal of β-hairpin 2. 1) Scheme of a starting construct Bba_K1352001; 2) theoretical construct with β-hairpin 2 removed; 3) Sequencing results of created Bba_K1352002 BioBrick; 4) Alignment of a) Bba_K1352001 and b) Bba_K1352002 construct sequences. Removal of β-hairpin 2 clearly visible.



Fig.9    Translation of: Query - Bba_K1352001; Subject - Bba_K1352002. Translation of β-hairpin sequences indicated in yellow.


7. Testing the physiology and function of Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002)


a) Testing the aggregation properties of Ag43+FLAG+MCS

Overnight cultures of Ag43+FLAG+MCS, Ag43+FLAG+MCS(-)β-hairpins and Ag43 were transferred onto sterile glass test tubes, induced with 0.2% arabinose and incubated in a shaking water bath at 37oC for >2hrs. Subsequently, test tubes were removed from the water bath and photographed for visual investigation for aggregation.


Fig.10    Aggregation after induction with 0.2% arabinose of A) Ag43 without FLAG (Bba_K1352000); B) Ag43+FLAG+MCS (Bba_K1352001); Ag43+FLAG+MCS(-)β-hairpins (Bba_K1352002).

A clear difference is visible between aggregation levels of tested BioBricks. Ag43 clearly aggregates when induced with arabinose. Suprisingly, Ag43+FLAG+MCS does not display aggregation properties, even though it possesses β-hairpin sequences. We hypothesize that insertion of foreign peptide sequences, in this case FLAG tag epitope, slightly changes the shape of Ag43 at places critical for clumping and disrupts velcro-like mechanism of aggregation. Ag43+FLAG+MCS(-)β-hairpins also does not display any aggregation properties. Although we cannot confirm that this is due to removal of β-hairpin sequences and not presence of a FLAG tag epitope sequence due to lack of Ag43(-)FLAG(-)β-hairpins, literature evidence provided evidence that the lack of aggregation properties is due to removal of β-hairpins and would persist if FLAG+MCS were removed (Heras et. al., 2014).

Since the lack of aggregation properties in Bba_K1352001 may be foreign peptide sequence specific, created BioBrick Bba_K1352002 which lacks β-hairpins is still a useful construct which can be utilized in a range of projects where aggregation is undesirable.

Note: Further characterization is needed in order to determine whether removal of β-hairpin sequences does not interfere with foreign peptides expression on cell surface membrane.



References


1)    Heras, B., Totsika, M., Peters, K. M., Paxman, J. J., Gee, C. L., Jarrott, R. J., & Schembri, M. A. (2014). The antigen 43 structure reveals a molecular Velcro-like mechanism of autotransporter-mediated bacterial clumping. Proceedings of the National Academy of Sciences, 111(1), 457-462.
2)    Kjærgaard, K., Schembri, M. A., Hasman, H., & Klemm, P. (2000). Antigen 43 from Escherichia coli induces inter-and intraspecies cell aggregation and changes in colony morphology of Pseudomonas fluorescens. Journal of bacteriology, 182(17), 4789-4796.
3)    Kjærgaard, K., Hasman, H., Schembri, M. A., & Klemm, P. (2002). Antigen 43-mediated autotransporter display, a versatile bacterial cell surface presentation system. Journal of bacteriology, 184(15), 4197-4204.
4)    Van der Woude, M. W., & Henderson, I. R. (2008). Regulation and function of Ag43 (flu). Annu. Rev. Microbiol., 62, 153-169.