Team:Technion/Project/Reporter

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<ol>
<ol>
   <li><span dir="ltr"> </span><strong>Alkaline Phosphatase Assay</strong>: In <em>E.  coli</em>, alkaline phosphatase (ALP) is encoded by the <em>phoA</em> gene. The wild  type <em>phoA</em> gene from Citrobacter has a signal sequence directing export  of alkaline phosphatase into the periplasm, where it is active. In this  protocol, the colorless substrate p-nitrophenyl phosphate (PNPP) is hydrolyzed  by ALP, producing nitrophenol, a yellow color product, which is quantified by  an assay at a maximum absorbance 420 nm.</li>
   <li><span dir="ltr"> </span><strong>Alkaline Phosphatase Assay</strong>: In <em>E.  coli</em>, alkaline phosphatase (ALP) is encoded by the <em>phoA</em> gene. The wild  type <em>phoA</em> gene from Citrobacter has a signal sequence directing export  of alkaline phosphatase into the periplasm, where it is active. In this  protocol, the colorless substrate p-nitrophenyl phosphate (PNPP) is hydrolyzed  by ALP, producing nitrophenol, a yellow color product, which is quantified by  an assay at a maximum absorbance 420 nm.</li>
-
   <li><span dir="ltr"> </span><strong><em>xyIE</em></strong><strong> Assay:</strong> The xylE  gene from <em>Pseudomonas putida</em> TOL  pWW0. This gene encodes the enzyme catechol-2,3-dioxygenase  (metapyrocatechase), which converts catechol to the bright yellow product  2-hydroxy-cis,cis-muconic semialdehyde. This is a useful reporter gene;  colonies or broths expressing active XylE, in the presence of oxygen, will  rapidly convert catechol, a cheap colorless substrate, to a bright yellow compound  with an absorbance maximum around 380 nm. </li>
+
   <li><span dir="ltr"> </span><strong><em>xylE</em></strong><strong> Assay:</strong> The xylE  gene from <em>Pseudomonas putida</em> TOL  pWW0. This gene encodes the enzyme catechol-2,3-dioxygenase  (metapyrocatechase), which converts catechol to the bright yellow product  2-hydroxy-cis,cis-muconic semialdehyde. This is a useful reporter gene;  colonies or broths expressing active XylE, in the presence of oxygen, will  rapidly convert catechol, a cheap colorless substrate, to a bright yellow compound  with an absorbance maximum around 380 nm. </li>
   <li><span dir="ltr"> </span><strong>Promoters: </strong>In order to  check as many different polymerases to see with which set of enzymes we achieve  minimum cross-reactivity, we worked with 5 polymerases. Both the polymerases  and their matching promoters were acquired from Christopher A. Voigt1.  He sent us the four RNA polymerases promoters: pT7*,p T3, pK1F, and pN4 with a  T7 terminator at the end.<strong> </strong>These four plasmids will also function as our  backbone plasmids, and to them we'll clone the assay genes along with their  RBS. The Sp6 promoter was added via PCR over the T7 promoter.<strong></strong></li>
   <li><span dir="ltr"> </span><strong>Promoters: </strong>In order to  check as many different polymerases to see with which set of enzymes we achieve  minimum cross-reactivity, we worked with 5 polymerases. Both the polymerases  and their matching promoters were acquired from Christopher A. Voigt1.  He sent us the four RNA polymerases promoters: pT7*,p T3, pK1F, and pN4 with a  T7 terminator at the end.<strong> </strong>These four plasmids will also function as our  backbone plasmids, and to them we'll clone the assay genes along with their  RBS. The Sp6 promoter was added via PCR over the T7 promoter.<strong></strong></li>
   <li><span dir="ltr"> </span><strong>Controls: </strong></li>
   <li><span dir="ltr"> </span><strong>Controls: </strong></li>
   <ol>
   <ol>
-
     <li><span dir="ltr"> </span><u>Positive</u>- In order to see whether our assay's genes, <em>phoA</em> and <em>xyIE</em>, work properly and generate a colored output, we created a  positive control. The positive control will consist of a Tetracycline  repressible promoter (pTetO) before each of the assay's genes. In the absence of an inducer, TetR binds to tetO  and prevents transcription. It can be turned on when an inducer, such as  tetracycline, binds to TetR and causes a conformation change that prevents TetR  from remaining bound to the operator. [[File:assay_figure2.jpg|300px|thumb|right|<strong><em>Figure 2: </em></strong><em>an illustration of the pET system as designed originally [A] and our own  pET as used in our experiment [B]</em>]]
+
     <li><span dir="ltr"> </span><u>Positive</u>- In order to see whether our assay's genes, <em>phoA</em> and <em>xylE</em>, work properly and generate a colored output, we created a  positive control. The positive control will consist of a Tetracycline  repressible promoter (pTetO) before each of the assay's genes. In the absence of an inducer, TetR binds to tetO  and prevents transcription. It can be turned on when an inducer, such as  tetracycline, binds to TetR and causes a conformation change that prevents TetR  from remaining bound to the operator. [[File:assay_figure2.jpg|300px|thumb|right|<strong><em>Figure 2: </em></strong><em>an illustration of the pET system as designed originally [A] and our own  pET as used in our experiment [B]</em>]]
When the operator site is not bound, the  activity of the promoter is restored. Unfortunately,  we don't have a bacterium strain with the repressor we plan to use the pTetO as  a constitutive promoter.</li>
When the operator site is not bound, the  activity of the promoter is restored. Unfortunately,  we don't have a bacterium strain with the repressor we plan to use the pTetO as  a constitutive promoter.</li>
     <li><span dir="ltr"> </span><u>Negative</u>: We have two kinds of negative controls: The  first one is to see whether we get any absorbance without the presence of the  assay parts, promoter + assay gene. The second one is to measure the leakage of  the polymerase promoters. For that reason, we will measure the absorbance of  the promoter plasmids without the polymerase genes.&nbsp; </li>
     <li><span dir="ltr"> </span><u>Negative</u>: We have two kinds of negative controls: The  first one is to see whether we get any absorbance without the presence of the  assay parts, promoter + assay gene. The second one is to measure the leakage of  the polymerase promoters. For that reason, we will measure the absorbance of  the promoter plasmids without the polymerase genes.&nbsp; </li>
   </ol>
   </ol>
-
   <li><span dir="ltr"> </span><strong>pET Expression System: </strong>In order to  characterize our assay, we intend to use the pET expression system. The host  cell for the pET expression system is a bacteria which has been genetically  engineered to incorporate the gene for T7 RNA polymerase, the lac promoter and  the lac operator in its genome (BL21 strain). When lactose or a molecule  similar to lactose is present inside the cell, transcription of the T7 RNA  polymerase is activated.<strong> </strong>Therefore, we have a similar system to the T7  RNA polymerase plasmid that we intended to create in the first place. By  transformation of our pT7 test plasmid to the engineered bacteria with the  endogenous T7 polymerase gene, we can characterize our pT7 test plasmid. By adding  rising concentrations of the inducer, IPTG, and measuring the absorbance for  each one, we can deduce whether we have a rising concentration of our assay  genes, <em>phoA</em> and <em>xyIE</em>. However, this only works in bulk or culture  assay and not single cell assays, since in single cells the lac system is  on/off. Meaning that at low concentrations of IPTG some cells will turn on,  while the rest will be off. An illustration of the normal pET system and our  &quot;made&quot; system is shown in <strong><em>Figure 2</em></strong>.</li>
+
   <li><span dir="ltr"> </span><strong>pET Expression System: </strong>In order to  characterize our assay, we intend to use the pET expression system. The host  cell for the pET expression system is a bacteria which has been genetically  engineered to incorporate the gene for T7 RNA polymerase, the lac promoter and  the lac operator in its genome (BL21 strain). When lactose or a molecule  similar to lactose is present inside the cell, transcription of the T7 RNA  polymerase is activated.<strong> </strong>Therefore, we have a similar system to the T7  RNA polymerase plasmid that we intended to create in the first place. By  transformation of our pT7 test plasmid to the engineered bacteria with the  endogenous T7 polymerase gene, we can characterize our pT7 test plasmid. By adding  rising concentrations of the inducer, IPTG, and measuring the absorbance for  each one, we can deduce whether we have a rising concentration of our assay  genes, <em>phoA</em> and <em>xylE</em>. However, this only works in bulk or culture  assay and not single cell assays, since in single cells the lac system is  on/off. Meaning that at low concentrations of IPTG some cells will turn on,  while the rest will be off. An illustration of the normal pET system and our  &quot;made&quot; system is shown in <strong><em>Figure 2</em></strong>.</li>
</ol>
</ol>
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===The Assay Genes===
===The Assay Genes===
[[File:assay_figure3.jpg|250px|thumb|right|<strong><em>Figure 3</em></strong><em>: gel electrophoresis for the PCR results of all the promoter backbone  plasmids. Expected size: 3400 bp.&nbsp; The  left lane is a standard 1 Kb ladder (NEB)<strong>. A-</strong> Only the T7 promoter  yielded positive results. <strong>B-</strong> Only the K1F promoter yielded positive  results. <strong>C-</strong> the remaining promoters- T3,N4 and SP6 yielded positive  results. </em>]]
[[File:assay_figure3.jpg|250px|thumb|right|<strong><em>Figure 3</em></strong><em>: gel electrophoresis for the PCR results of all the promoter backbone  plasmids. Expected size: 3400 bp.&nbsp; The  left lane is a standard 1 Kb ladder (NEB)<strong>. A-</strong> Only the T7 promoter  yielded positive results. <strong>B-</strong> Only the K1F promoter yielded positive  results. <strong>C-</strong> the remaining promoters- T3,N4 and SP6 yielded positive  results. </em>]]
-
<p>In order to  have our assay ready we ordered the Alkaline Phosphatase reporter gene, <em>phoA</em>,  from the registry (BBa_J61032). We already had the <em>xyIE</em> reporter gene in  the distribution kit (BBa_J33204). We added XhoI and XmaI restriction sites in  both ends of the parts via PCR, for the <em>phoA</em> gene we also added an RBS  (BBa_B0064). Since the phoA sequence was reported to be inconsistent we sequenced it and found that  there was only one silent mutation in the <em>phoA</em> CDS. </p>
+
<p>In order to  have our assay ready we ordered the Alkaline Phosphatase reporter gene, <em>phoA</em>,  from the registry (BBa_J61032). We already had the <em>xylE</em> reporter gene in  the distribution kit (BBa_J33204). We added XhoI and XmaI restriction sites in  both ends of the parts via PCR, for the <em>phoA</em> gene we also added an RBS  (BBa_B0064). Since the phoA sequence was reported to be inconsistent we sequenced it and found that  there was only one silent mutation in the <em>phoA</em> CDS. </p>
===The Promoter Plasmids===
===The Promoter Plasmids===
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===Restriction,  Ligation and Transformation ===
===Restriction,  Ligation and Transformation ===
[[File:assay_figure4.jpg|250px|thumb|left|<strong><em>Figure 4:</em></strong><em> gel electrophoresis for the Colony PCR results  of all the plasmids with phoA as an insert. Expected size: 1750 bp . The left  lane is a standard 1 Kb ladder (NEB)<strong>. </strong>&nbsp;<strong>A-</strong> Four positive colonies for the pT7  backbone can be seen; control stands for PCR mix without a colony<strong>. B-</strong> Two positive colonies for the pN4 and pT3 backbones can be seen; the control is  a ligation reaction without an insert. <strong>C-</strong> One positive colony for the  pSp6 backbone can be seen; control is the PCR mix without a colony.</em>]]
[[File:assay_figure4.jpg|250px|thumb|left|<strong><em>Figure 4:</em></strong><em> gel electrophoresis for the Colony PCR results  of all the plasmids with phoA as an insert. Expected size: 1750 bp . The left  lane is a standard 1 Kb ladder (NEB)<strong>. </strong>&nbsp;<strong>A-</strong> Four positive colonies for the pT7  backbone can be seen; control stands for PCR mix without a colony<strong>. B-</strong> Two positive colonies for the pN4 and pT3 backbones can be seen; the control is  a ligation reaction without an insert. <strong>C-</strong> One positive colony for the  pSp6 backbone can be seen; control is the PCR mix without a colony.</em>]]
-
[[File:assay_figure5.jpg|250px|thumb|right|<strong><em>Figure 5:</em></strong><em> gel electrophoresis picture for the colony PCR  results of all the plasmids with xyIE as an insert. Expected size: 1200 bp. The  left lane is a standard 1 Kb ladder (NEB)<strong>. </strong>&nbsp;<strong>A-</strong> One positive colony for the pT7  backbone can be seen; control stands for PCR mix without a colony. <strong>B-</strong> At  least one positive colony for the pT3, pN4, pK1F and pSP6 backbones can be  seen; the pT3 and pSP6 controls stands for a ligation reaction without an  insert, the &quot;control- no colony&quot; stands for the PCR mix without a  colony.</em>]]
+
[[File:assay_figure5.jpg|250px|thumb|right|<strong><em>Figure 5:</em></strong><em> gel electrophoresis picture for the colony PCR  results of all the plasmids with xylE as an insert. Expected size: 1200 bp. The  left lane is a standard 1 Kb ladder (NEB)<strong>. </strong>&nbsp;<strong>A-</strong> One positive colony for the pT7  backbone can be seen; control stands for PCR mix without a colony. <strong>B-</strong> At  least one positive colony for the pT3, pN4, pK1F and pSP6 backbones can be  seen; the pT3 and pSP6 controls stands for a ligation reaction without an  insert, the &quot;control- no colony&quot; stands for the PCR mix without a  colony.</em>]]
-
<p>We performed  restriction with XhoI and XmaI restriction enzymes on both the plasmids and the  inserts (<em>phoA</em> and <em>xyIE</em>) and ligated them together. In order to  check whether the ligation was successful and we got ourselves new BioBricks we  did a colony PCR with one primer for the insert and one for the plasmid.<br />
+
<p>We performed  restriction with XhoI and XmaI restriction enzymes on both the plasmids and the  inserts (<em>phoA</em> and <em>xylE</em>) and ligated them together. In order to  check whether the ligation was successful and we got ourselves new BioBricks we  did a colony PCR with one primer for the insert and one for the plasmid.</p><br />
====<em>phoA</em> Colony PCR====
====<em>phoA</em> Colony PCR====
<p>As  shown in <strong><em>Figure 4</em></strong>, we managed to ligate the <em>phoA</em> insert  with most of our backbones, except for the K1F promoter backbone. This means  that we got 4 new BioBricks :)</p>
<p>As  shown in <strong><em>Figure 4</em></strong>, we managed to ligate the <em>phoA</em> insert  with most of our backbones, except for the K1F promoter backbone. This means  that we got 4 new BioBricks :)</p>
-
====<em>xyIE</em> colony PCR====
+
====<em>xylE</em> colony PCR====
-
<p>As shown in <strong><em>Figure  5</em></strong>, we managed to ligate the <em>xyIE</em> insert with all of our  backbones. This means that we got 5 new BioBricks :)<br />
+
<p>As shown in <strong><em>Figure  5</em></strong>, we managed to ligate the <em>xylE</em> insert with all of our  backbones. This means that we got 5 new BioBricks :)<br />
<br clear="all" /></p>
<br clear="all" /></p>
 +
===Controls===
===Controls===
====Positive Controls====
====Positive Controls====
[[File:assay_figure6.jpg|250px|thumb|right|<strong><em>Figure 6: </em></strong><em>&nbsp;gel electrophoresis for the PCR results of the  positive control backbone (triplicate). Expected size: 2300 bp.</em><em> The left lane is a standard 1 Kb ladder (NEB)<strong>.</strong></em>]]
[[File:assay_figure6.jpg|250px|thumb|right|<strong><em>Figure 6: </em></strong><em>&nbsp;gel electrophoresis for the PCR results of the  positive control backbone (triplicate). Expected size: 2300 bp.</em><em> The left lane is a standard 1 Kb ladder (NEB)<strong>.</strong></em>]]
-
<p>As mentioned  before, after we made our new BioBricks we wanted to know whether the genes are  expressed and the assays actually work. So we ligated our inserts- <em>phoA</em> and <em>xyIE</em>, to a backbone from the distribution kit (BBa_I13600), which  contained the pTetO promoter along with an engineered CFP (eCFP) gene which we  removed by PCR. We also added XhoI and XmaI restriction sites in both ends of  the plasmid.&nbsp; <br />
+
<p>As mentioned  before, after we made our new BioBricks we wanted to know whether the genes are  expressed and the assays actually work. So we ligated our inserts- <em>phoA</em> and <em>xylE</em>, to a backbone from the distribution kit (BBa_I13600), which  contained the pTetO promoter along with an engineered CFP (eCFP) gene which we  removed by PCR. We also added XhoI and XmaI restriction sites in both ends of  the plasmid.&nbsp; <br />
As shown in <strong><em>Figure  6</em></strong>, the experiment yielded a positive result. <br />
As shown in <strong><em>Figure  6</em></strong>, the experiment yielded a positive result. <br />
   <br /></p>
   <br /></p>
-
[[File:assay_figure7.jpg|250px|thumb|left|Figure 7: gel electrophoresis for the colony PCR results of the positive control plasmids with each insert. Expected size for phoA: 3750 bp, and for xyIE: 3250 bp. The left lane is a standard 1 Kb ladder (NEB).]]
+
[[File:assay_figure7.jpg|250px|thumb|left|<strong><em>Figure 7:</em></strong><em> gel electrophoresis for the colony PCR results of the positive control plasmids with each insert. Expected size for phoA: 3750 bp, and for xylE: 3250 bp. The left lane is a standard 1 Kb ladder (NEB)<strong>.</strong></em>]]
=====Restriction, Ligation and Transformation=====
=====Restriction, Ligation and Transformation=====
-
We performed  restriction with XhoI and XmaI restriction enzymes on both the plasmids and the  inserts (<em>phoA</em> and <em>xyIE</em>) and ligated them together. In order to  check whether the ligation was successful and we got ourselves new BioBricks we  did a colony PCR with one primer for the insert and one for the plasmid.  uniform <br />
+
<p>We performed  restriction with XhoI and XmaI restriction enzymes on both the plasmids and the  inserts (<em>phoA</em> and <em>xylE</em>) and ligated them together. In order to  check whether the ligation was successful and we got ourselves new BioBricks we  did a colony PCR with one primer for the insert and one for the plasmid.  uniform </p>
-
As shown in <strong><em>Figure  7</em></strong>, we had positive colonies only for the <em>xyIE</em> and not for the <em>phoA</em>.<br />
+
<p>As shown in <strong><em>Figure  7</em></strong>, we had positive colonies only for the <em>xylE</em> and not for the <em>phoA</em>.<br clear="all" /></p>
 +
<p>As shown in <strong><em>Figure 8</em></strong>, a distinct yellowish hue in the <em>xylE</em> assay was  detected after the substrate was added, which means our <em>xylE</em> gene works  as planned.</p>
 +
[[File:assay_figure8.jpg|250px|thumb|center|<strong><em>Figure 8:</em></strong><em> Presents a starter of the BL21 bacteria with the pTetO + xylE plasmid. On the left is a tube with the addition of catechol, on the right is the one without an addition of catechol.</em>]]
 +
====Negative Controls====
 +
<ol>
 +
  <li><span dir="ltr"> </span>The first negative control is a  bacteria without the assay genes, which means the bacteria contains only the  PET system. The results of the absorbance After induction with IPTG and  performing the assays protocols are shown in <strong>''Table 1''</strong>:
 +
<p align="center">'''''Table 1:''' Absorbance results for the first negative  control, after blank reduction, for <em>xylE</em> and <em>phoA</em> assays after  induction with IPTG''</p>
 +
<div align="center">
 +
  <table id="table1">
 +
    <tr>
 +
      <td valign="top"><p align="center"><strong>&nbsp;</strong></p></td>
 +
      <td nowrap="nowrap" valign="bottom"><p align="center"><strong>Absorbance</strong></p></td>
 +
    </tr>
 +
    <tr>
 +
      <td valign="bottom"><p align="center"><em>xylE</em> assay(380 nm)</p></td>
 +
      <td nowrap="nowrap" valign="bottom"><p align="center">0.064</p></td>
 +
    </tr>
 +
    <tr>
 +
      <td valign="bottom"><p align="center"><em>phoA</em> assay (420 nm)</p></td>
 +
      <td nowrap="nowrap" valign="bottom"><p align="center">0.000*</p></td>
 +
    </tr>
 +
  </table>
 +
</div>
 +
<span dir="ltr"> </span>* Because of the blank reduction  the absorbance was negative, which is not a valid absorbance.
 +
<p>As seen in the results, the absorbance acquired  from the assays was very low. This indicates that there hasn't been enough  enzyme in the bacteria that could have caused the yellow color. </p></li>
 +
<li><span dir="ltr"> </span>The second negative control is  a bacteria containing only the assay part- T7 promoter+ <em>xylE</em>\<em>phoA</em> genes, without any RNAP. The results of the absorbance after performing the  assays protocols are shown in <strong>''Table 2''</strong>:
 +
<p align="center">'''''Table 2:''' Absorbance  results for second negative control after blank reduction for <em>xylE</em> and <em>phoA</em>''</p>
 +
<div align="center">
 +
  <table id="table1" width="208">
 +
    <tr>
 +
      <td width="128" valign="top"><p align="center">&nbsp;</p></td>
 +
      <td width="80" nowrap="nowrap" valign="bottom"><p align="center"><strong>Absorbance</strong><strong> </strong></p></td>
 +
    </tr>
 +
    <tr>
 +
      <td width="128" valign="bottom"><p align="center"><em>xylE</em> (380 nm) </p></td>
 +
      <td nowrap="nowrap" valign="bottom"><p align="center">1.200 </p></td>
 +
    </tr>
 +
    <tr>
 +
      <td width="128" valign="bottom"><p align="center"><em>phoA</em> (420 nm) </p></td>
 +
      <td nowrap="nowrap" valign="bottom"><p align="center">0.171 </p></td>
 +
    </tr>
 +
  </table>
 +
</div>
 +
<p>As  seen in the results, the absorbance yielded from the assays was low in comparison  to the assay results from the pET experiment, [0.5 to 1.5] for the <em>phoA</em> and [10 to 60] for the <em>xylE</em>. This indicates that the T7 promoter has a  very low leakage level.</p>
 +
</li>
 +
</ol>
 +
 
 +
===Characterization of the Assays===
 +
<p>As mentioned  before, the characterization of the parts [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784000 BBa_K784000- pT7+phoA] and [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784001 BBa_K784001-pT7+xylE] will be done by adding different concentrations of  the inducer, IPTG, while the saturation time and amount of substrate for the  assay are identical.</p>
 +
====Alkaline Phosphatase====
 +
<p>The graph  below presents the results of the experiment described. The absorbance at 420nm  for each of the different concentrations of the inducer in a range of 0.5 &#956;&#924; to 1000  &#956;&#924; on a logarithmic scale. The absorbance was calculated via  different dilutions of the samples: dilutions by 0.5, by 0.25, and by 0.1. The  error bars represent the processing of the data collected. The line at the  bottom of the graph represents the basal level according to the control result-  no IPTG induction.</p>
 +
[[File:assay_figure9.jpg|400px|thumb|center|<em><strong>Figure  9</strong>: absorbance at 420nm against concentration of inducer </em>]]
 +
<p>As can be seen, the graph shows a clear positive  tendency- the higher the concentration the higher the absorption, as expected. Starting  from a concentration of &nbsp;40 &#956;M and above, there are only small deviations from  the absorption value of&nbsp; 1.2, probably  due to the fact that saturation has been achieved. </p>
 +
====<em>xylE</em>====
 +
<p>The graph  below presents the results of the experiment described. The absorbance at 380nm  for each of the different concentrations of the inducer in a range of 0.5  &#956;M to 500 &#956;M on a  logarithmic scale. The absorbance was calculated via different dilutions of the  samples: dilutions by 0.5, by 0.25, and by 0.1. The error bars represent the  processing of the data collected. The line at the bottom of the graph  represents the basal level according to the control result- no IPTG induction.</p>
 +
[[File:assay_figure10.jpg|400px|thumb|center|<em><strong>Figure  10</strong>: absorbance at 380nm against concentration of inducer.</em>]]
 +
<p>As can be seen, the graph shows a small tendency  to rise, but it's not clear enough. There are several explanations, one is that saturation has been achieved  from lowest concentration measured, which shows both that the assay is highly  sensitive and that a small amount of polymerase is enough to cause translation.  The experiment should be repeated with either lower concentrations of IPTG or  Catechol. The line at the bottom of the graph represents the basal level  according to the control result- no IPTG induction</p>
 +
 
 +
==Conclusions and summary==
 +
<ul>
 +
<li><span dir="ltr"> </span>We have produced two separate assays for testing the presence of the RNA polymerases that is used for the  induction of the phage.</li>
 +
<li><span dir="ltr"> </span>We have tested two parts [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784000 BBa_K784000- pT7+phoA] and [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784001 BBa_K784001-pT7+xylE] and found it fully functional.</li>
 +
  <li><span dir="ltr"> </span>Since both of our assays show  very low leakage the possibility of getting a false positive result is not  high.</li>
 +
  <li><span dir="ltr"> </span>Since in both cases very small  amounts of IPTG showed positive results, we can deduce that even a small amount  of the RNA polymerase can activate the promoters. In terms of the Trojan Phage,  that can create a situation that even if there are no activators present in the  cell, the leakage of the polymerase promoters can create enough polymerases to  translate the phage's proteins and cause lysis. </li>
 +
 
 +
==Best BioBrick Measurement Approach:==
 +
 
 +
<p>We have developed an assay that can be used to test the activity of the T7 polymerase, or any polymerase, by using any of the similar plasmids that we have made or by simply replacing the promoter using Xbal and XhoI restriction enzymes.
 +
However, it can also act as a reporter system for the production of any part by a simple cloning step: first extracting the RBS+xylE / RBS+ALP part via XhoI and XmaI and inserting it into any plasmid that holds a desired gene. By performing the assay, one can measure the amount of the part translated according to the intensity of the color. It can be used instead of a fluorescent gene or as an addition to one. <br> <br>
 +
 
 +
Moreover, combined with the pET system, or one of our polymerase plasmids, the systems can be used as an inducible production systems for any Biobrick, that can also measure  the amount produced. In order to use it in this manner, one has to insert the required part with an RBS after the T7 promoter via XhoI, transfer it to a bacteria with the standard pET system, and add the desired amount of inducer, IPTG, according to the graph presented in the experience part in the registry. The result is an inducible system in which the user can choose the production amount of any chosen Biobrick and verify it by the colored assay.<br><br>
 +
 
 +
If by simply adding another measurement option, as an alternative to fluorescent genes, or by creating an inducible measurable production system, we have created an important, easy- to- use Biobricks  that can be used as measurement systems in a wide range of applications.
 +
 
 +
==References==
 +
<ol>
 +
  <li><span dir="ltr"> </span><strong>Temme K., et al.</strong> 2012. Modular control of multiple pathways using  engineered orthogonal T7 polymerases. Nucleic Acids Research (advance access):  1-9.</li>
 +
  <li><span dir="ltr"> </span><strong>Shin I., Kang C.</strong> 2003. Mutational analysis and structure of the  phage SP6 promoter. Methods in Enzymology <strong>370</strong>: 658-668.</li>
 +
</ol>

Latest revision as of 09:52, 21 November 2012



Contents

Objective

Figure 1: Assay Plasmids' cassettes.

There are two parts in our system, the Phage and the E. coli. Before we can test them together, we have to make sure that our parts work individually. For that purpose, we allocated two team members to create assays that can test the function of our E. coli parts, the inducible RNA polymerases, and characterize them.
The cassettes that are used in the plasmids are shown in Figure 1.

Work plan

We intend to create two colored assays that can indicate and quantify the expression of the different polymerases from our plasmids. Each assay gene will be cloned after each of the RNA polymerase promoters, so that the expression of the polymerases will be linked to the color developed. Before using them with the designated RNA polymerase plasmid, we intend to characterize them by using different inducer concentrations and measuring the absorbance.
Main Parts:

  1. Alkaline Phosphatase Assay: In E. coli, alkaline phosphatase (ALP) is encoded by the phoA gene. The wild type phoA gene from Citrobacter has a signal sequence directing export of alkaline phosphatase into the periplasm, where it is active. In this protocol, the colorless substrate p-nitrophenyl phosphate (PNPP) is hydrolyzed by ALP, producing nitrophenol, a yellow color product, which is quantified by an assay at a maximum absorbance 420 nm.
  2. xylE Assay: The xylE gene from Pseudomonas putida TOL pWW0. This gene encodes the enzyme catechol-2,3-dioxygenase (metapyrocatechase), which converts catechol to the bright yellow product 2-hydroxy-cis,cis-muconic semialdehyde. This is a useful reporter gene; colonies or broths expressing active XylE, in the presence of oxygen, will rapidly convert catechol, a cheap colorless substrate, to a bright yellow compound with an absorbance maximum around 380 nm.
  3. Promoters: In order to check as many different polymerases to see with which set of enzymes we achieve minimum cross-reactivity, we worked with 5 polymerases. Both the polymerases and their matching promoters were acquired from Christopher A. Voigt1. He sent us the four RNA polymerases promoters: pT7*,p T3, pK1F, and pN4 with a T7 terminator at the end. These four plasmids will also function as our backbone plasmids, and to them we'll clone the assay genes along with their RBS. The Sp6 promoter was added via PCR over the T7 promoter.
  4. Controls:
    1. Positive- In order to see whether our assay's genes, phoA and xylE, work properly and generate a colored output, we created a positive control. The positive control will consist of a Tetracycline repressible promoter (pTetO) before each of the assay's genes. In the absence of an inducer, TetR binds to tetO and prevents transcription. It can be turned on when an inducer, such as tetracycline, binds to TetR and causes a conformation change that prevents TetR from remaining bound to the operator.
      Figure 2: an illustration of the pET system as designed originally [A] and our own pET as used in our experiment [B]
      When the operator site is not bound, the activity of the promoter is restored. Unfortunately, we don't have a bacterium strain with the repressor we plan to use the pTetO as a constitutive promoter.
    2. Negative: We have two kinds of negative controls: The first one is to see whether we get any absorbance without the presence of the assay parts, promoter + assay gene. The second one is to measure the leakage of the polymerase promoters. For that reason, we will measure the absorbance of the promoter plasmids without the polymerase genes. 
  5. pET Expression System: In order to characterize our assay, we intend to use the pET expression system. The host cell for the pET expression system is a bacteria which has been genetically engineered to incorporate the gene for T7 RNA polymerase, the lac promoter and the lac operator in its genome (BL21 strain). When lactose or a molecule similar to lactose is present inside the cell, transcription of the T7 RNA polymerase is activated. Therefore, we have a similar system to the T7 RNA polymerase plasmid that we intended to create in the first place. By transformation of our pT7 test plasmid to the engineered bacteria with the endogenous T7 polymerase gene, we can characterize our pT7 test plasmid. By adding rising concentrations of the inducer, IPTG, and measuring the absorbance for each one, we can deduce whether we have a rising concentration of our assay genes, phoA and xylE. However, this only works in bulk or culture assay and not single cell assays, since in single cells the lac system is on/off. Meaning that at low concentrations of IPTG some cells will turn on, while the rest will be off. An illustration of the normal pET system and our "made" system is shown in Figure 2.

Results

The Assay Genes

Figure 3: gel electrophoresis for the PCR results of all the promoter backbone plasmids. Expected size: 3400 bp.  The left lane is a standard 1 Kb ladder (NEB). A- Only the T7 promoter yielded positive results. B- Only the K1F promoter yielded positive results. C- the remaining promoters- T3,N4 and SP6 yielded positive results.

In order to have our assay ready we ordered the Alkaline Phosphatase reporter gene, phoA, from the registry (BBa_J61032). We already had the xylE reporter gene in the distribution kit (BBa_J33204). We added XhoI and XmaI restriction sites in both ends of the parts via PCR, for the phoA gene we also added an RBS (BBa_B0064). Since the phoA sequence was reported to be inconsistent we sequenced it and found that there was only one silent mutation in the phoA CDS.

The Promoter Plasmids

Due to the fact that the promoter plasmids had an mRFP gene between the promoter and the terminator, we ran another PCR in order to delete it, in which the primers were at both ends of the mRFP facing outwards. In order to have a fifth plasmid with the SP6 promoter2 we performed another PCR, only with different primers: we engineered primers that had the Sp6 promoter in them while the template was an pT7 plasmid. This way, the T7 promoter was replaced with the Sp6 promoter. In all of the reactions described above, we added XhoI and XmaI restriction sites in both ends of the plasmids.
As shown in Figure 3 we managed to get all the backbones in the right size. The first run we had a positive result only with the pT7 backbone, the second run we had only the K1F backbone and in the third run, after raising the Tm by 10 degrees, we had the rest of the plasmids backbones- T3, N4 and SP6.

Restriction, Ligation and Transformation

Figure 4: gel electrophoresis for the Colony PCR results of all the plasmids with phoA as an insert. Expected size: 1750 bp . The left lane is a standard 1 Kb ladder (NEB).  A- Four positive colonies for the pT7 backbone can be seen; control stands for PCR mix without a colony. B- Two positive colonies for the pN4 and pT3 backbones can be seen; the control is a ligation reaction without an insert. C- One positive colony for the pSp6 backbone can be seen; control is the PCR mix without a colony.
Figure 5: gel electrophoresis picture for the colony PCR results of all the plasmids with xylE as an insert. Expected size: 1200 bp. The left lane is a standard 1 Kb ladder (NEB).  A- One positive colony for the pT7 backbone can be seen; control stands for PCR mix without a colony. B- At least one positive colony for the pT3, pN4, pK1F and pSP6 backbones can be seen; the pT3 and pSP6 controls stands for a ligation reaction without an insert, the "control- no colony" stands for the PCR mix without a colony.

We performed restriction with XhoI and XmaI restriction enzymes on both the plasmids and the inserts (phoA and xylE) and ligated them together. In order to check whether the ligation was successful and we got ourselves new BioBricks we did a colony PCR with one primer for the insert and one for the plasmid.


phoA Colony PCR

As shown in Figure 4, we managed to ligate the phoA insert with most of our backbones, except for the K1F promoter backbone. This means that we got 4 new BioBricks :)

xylE colony PCR

As shown in Figure 5, we managed to ligate the xylE insert with all of our backbones. This means that we got 5 new BioBricks :)

Controls

Positive Controls

Figure 6:  gel electrophoresis for the PCR results of the positive control backbone (triplicate). Expected size: 2300 bp. The left lane is a standard 1 Kb ladder (NEB).

As mentioned before, after we made our new BioBricks we wanted to know whether the genes are expressed and the assays actually work. So we ligated our inserts- phoA and xylE, to a backbone from the distribution kit (BBa_I13600), which contained the pTetO promoter along with an engineered CFP (eCFP) gene which we removed by PCR. We also added XhoI and XmaI restriction sites in both ends of the plasmid. 
As shown in Figure 6, the experiment yielded a positive result.

Figure 7: gel electrophoresis for the colony PCR results of the positive control plasmids with each insert. Expected size for phoA: 3750 bp, and for xylE: 3250 bp. The left lane is a standard 1 Kb ladder (NEB).
Restriction, Ligation and Transformation

We performed restriction with XhoI and XmaI restriction enzymes on both the plasmids and the inserts (phoA and xylE) and ligated them together. In order to check whether the ligation was successful and we got ourselves new BioBricks we did a colony PCR with one primer for the insert and one for the plasmid. uniform

As shown in Figure 7, we had positive colonies only for the xylE and not for the phoA.

As shown in Figure 8, a distinct yellowish hue in the xylE assay was detected after the substrate was added, which means our xylE gene works as planned.

Figure 8: Presents a starter of the BL21 bacteria with the pTetO + xylE plasmid. On the left is a tube with the addition of catechol, on the right is the one without an addition of catechol.

Negative Controls

  1. The first negative control is a bacteria without the assay genes, which means the bacteria contains only the PET system. The results of the absorbance After induction with IPTG and performing the assays protocols are shown in Table 1:

    Table 1: Absorbance results for the first negative control, after blank reduction, for xylE and phoA assays after induction with IPTG

     

    Absorbance

    xylE assay(380 nm)

    0.064

    phoA assay (420 nm)

    0.000*

    * Because of the blank reduction the absorbance was negative, which is not a valid absorbance.

    As seen in the results, the absorbance acquired from the assays was very low. This indicates that there hasn't been enough enzyme in the bacteria that could have caused the yellow color.

  2. The second negative control is a bacteria containing only the assay part- T7 promoter+ xylE\phoA genes, without any RNAP. The results of the absorbance after performing the assays protocols are shown in Table 2:

    Table 2: Absorbance results for second negative control after blank reduction for xylE and phoA

     

    Absorbance

    xylE (380 nm)

    1.200

    phoA (420 nm)

    0.171

    As seen in the results, the absorbance yielded from the assays was low in comparison to the assay results from the pET experiment, [0.5 to 1.5] for the phoA and [10 to 60] for the xylE. This indicates that the T7 promoter has a very low leakage level.

Characterization of the Assays

As mentioned before, the characterization of the parts [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784000 BBa_K784000- pT7+phoA] and [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784001 BBa_K784001-pT7+xylE] will be done by adding different concentrations of the inducer, IPTG, while the saturation time and amount of substrate for the assay are identical.

Alkaline Phosphatase

The graph below presents the results of the experiment described. The absorbance at 420nm for each of the different concentrations of the inducer in a range of 0.5 μΜ to 1000 μΜ on a logarithmic scale. The absorbance was calculated via different dilutions of the samples: dilutions by 0.5, by 0.25, and by 0.1. The error bars represent the processing of the data collected. The line at the bottom of the graph represents the basal level according to the control result- no IPTG induction.

Figure 9: absorbance at 420nm against concentration of inducer

As can be seen, the graph shows a clear positive tendency- the higher the concentration the higher the absorption, as expected. Starting from a concentration of  40 μM and above, there are only small deviations from the absorption value of  1.2, probably due to the fact that saturation has been achieved.

xylE

The graph below presents the results of the experiment described. The absorbance at 380nm for each of the different concentrations of the inducer in a range of 0.5 μM to 500 μM on a logarithmic scale. The absorbance was calculated via different dilutions of the samples: dilutions by 0.5, by 0.25, and by 0.1. The error bars represent the processing of the data collected. The line at the bottom of the graph represents the basal level according to the control result- no IPTG induction.

Figure 10: absorbance at 380nm against concentration of inducer.

As can be seen, the graph shows a small tendency to rise, but it's not clear enough. There are several explanations, one is that saturation has been achieved from lowest concentration measured, which shows both that the assay is highly sensitive and that a small amount of polymerase is enough to cause translation. The experiment should be repeated with either lower concentrations of IPTG or Catechol. The line at the bottom of the graph represents the basal level according to the control result- no IPTG induction

Conclusions and summary

  • We have produced two separate assays for testing the presence of the RNA polymerases that is used for the induction of the phage.
  • We have tested two parts [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784000 BBa_K784000- pT7+phoA] and [http://partsregistry.org/wiki/index.php?title=Part:BBa_K784001 BBa_K784001-pT7+xylE] and found it fully functional.
  • Since both of our assays show very low leakage the possibility of getting a false positive result is not high.
  • Since in both cases very small amounts of IPTG showed positive results, we can deduce that even a small amount of the RNA polymerase can activate the promoters. In terms of the Trojan Phage, that can create a situation that even if there are no activators present in the cell, the leakage of the polymerase promoters can create enough polymerases to translate the phage's proteins and cause lysis.
  • Best BioBrick Measurement Approach:

    We have developed an assay that can be used to test the activity of the T7 polymerase, or any polymerase, by using any of the similar plasmids that we have made or by simply replacing the promoter using Xbal and XhoI restriction enzymes. However, it can also act as a reporter system for the production of any part by a simple cloning step: first extracting the RBS+xylE / RBS+ALP part via XhoI and XmaI and inserting it into any plasmid that holds a desired gene. By performing the assay, one can measure the amount of the part translated according to the intensity of the color. It can be used instead of a fluorescent gene or as an addition to one.

    Moreover, combined with the pET system, or one of our polymerase plasmids, the systems can be used as an inducible production systems for any Biobrick, that can also measure the amount produced. In order to use it in this manner, one has to insert the required part with an RBS after the T7 promoter via XhoI, transfer it to a bacteria with the standard pET system, and add the desired amount of inducer, IPTG, according to the graph presented in the experience part in the registry. The result is an inducible system in which the user can choose the production amount of any chosen Biobrick and verify it by the colored assay.

    If by simply adding another measurement option, as an alternative to fluorescent genes, or by creating an inducible measurable production system, we have created an important, easy- to- use Biobricks that can be used as measurement systems in a wide range of applications.

    References

    1. Temme K., et al. 2012. Modular control of multiple pathways using engineered orthogonal T7 polymerases. Nucleic Acids Research (advance access): 1-9.
    2. Shin I., Kang C. 2003. Mutational analysis and structure of the phage SP6 promoter. Methods in Enzymology 370: 658-668.