Difference between revisions of "Team:Freiburg/Results/Immobilization"

 
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<h1 style="text-align:right">Cell-Free Expression of Immobilized DNA</h1>
 
<h1 style="text-align:right">Cell-Free Expression of Immobilized DNA</h1>
 
<p>
 
<p>
An important advantage of the DiaCHIP is the possibility to ship and store information encoded by DNA. From a DNA template array protein arrays can be produced on demand. In order to obtain this template, DNA is fixed on a silicone slide forming one side of our microfluidic chamber. Making use of a cell-free expression system, the DNA can then be transcribed and translated into the respective proteins resulting in the final protein array. The coding sequence of the proteins is genetically fused to a tag allowing their binding to a specific surface on the opposite side of the chamber.  
+
An important advantage of the DiaCHIP is the possibility to ship and store information encoded by DNA. From a DNA template array protein arrays can be produced on demand. As DNA is far more resistant to diverse cues e.g. temperature. In order to obtain this template, DNA is fixed on a silicone slide forming one side of our microfluidic chamber. Making use of a cell-free expression system, the DNA can then be transcribed and translated into the encoded proteins resulting in the final protein array. The coding sequence of the proteins is genetically fused to a tag allowing their binding to a specific surface on the opposite side of the chamber.  
 
</p>
 
</p>
  
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                     <div class="thumbcaption">
 
                   </a>
 
                   </a>
                       <p><strong>Figure 1: Scheme of the APTES/PDITC surface.</strong> The PDMS surface is layered with PDITC. This enables the binding of the amino-labeled DNA.</p>
+
                       <p><strong>Figure 1: Scheme of the APTES/PDITC surface.</strong> The PDMS (red) is layered with APTES (light grey) and the amino-linker PDITC (dark grey). The hydroxy layer generated during plasma activation is represented in blue.</p>
 
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                   </div>
 
               </div>
 
               </div>
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<p>
 
<p>
The core component of the DiaCHIP is the microfluidic chamber composed of a glass slide for protein immobilization and a PDMS (polydimethylsiloxane) flow cell. The silicone PDMS needs to be activated to enable the generation of the DNA template array by binding of the respective sequences. <a href="https://2015.igem.org/Team:Freiburg/Project/Surface_Chemistry"target="_blank">Oxygen plasma</a> is used to first activate the surface of the PDMS slide. This allows to cover it with the silane APTES and finally apply the <a href="https://2015.igem.org/Team:Freiburg/Project/Surface_Chemistry"target="_blank">crosslinker PDITC</a>. The DNA sequence to be immobilized requires an amino group to be covalently immobilized on the PDITC surface. The structure of this surface is schematically visualized in figure 1. The same surface chemistry can be used to immobilize proteins unspecifically.
+
The core component of the DiaCHIP is the microfluidic chamber composed of a glass slide for protein immobilization and a PDMS (polydimethylsiloxane) flow cell. The silicone PDMS needs to be activated to enable the generation of the DNA template array by binding of the respective sequences. Oxygen plasma is used to initially activate the surface of the PDMS slide by generating a hydroxy layer. This allows linking the silane APTES and subsequently the crosslinker PDITC. In order to bind the DNA covalently to this surface the respective DNA sequence requires an N- or C-terminal amino group. The structure of this surface is schematically visualized in figure 1. This surface chemistry is identical to the protocol used to immobilize proteins on a glass slide unspecifically (see <a href="https://2015.igem.org/Team:Freiburg/Project/Surface_Chemistry" title="PDITC surface for immobilizing proteins" target="_blank">PDITC surface for immobilizing proteins</a>).
 
<br>
 
<br>
To obtain an expression cassette for GFP with such an amino group, the target sequence was amplified by PCR using an amino-labeled reverse primer. Additionally, the forward primer was labeled by the fluorescent dye Cy3 to enable visualization by fluorescence microscopy. Successful amplification of the target sequence was verified by agarose gel electrophoresis.
+
In order to obtain an expression cassette for GFP with an amino group, the target sequence was amplified by PCR using an amino-labeled reverse primer. Additionally, the forward primer was labeled by the fluorescent dye Cy3 to enable visualization by fluorescence microscopy. Successful amplification of the target sequence was verified by agarose gel electrophoresis.
 
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                 <div class="thumbinner">
                     <a href="https://static.igem.org/mediawiki/2015/thumb/f/f5/Freiburg_spotting_microarrayscanner.png/735px-Freiburg_spotting_microarrayscanner.png" class="lightbox_trigger">
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                     <a href="https://static.igem.org/mediawiki/2015/e/e9/Freiburg_DNAonPDMS.png" class="lightbox_trigger">
                     <img src="https://static.igem.org/mediawiki/2015/thumb/f/f5/Freiburg_spotting_microarrayscanner.png/735px-Freiburg_spotting_microarrayscanner.png" width="250px">   
+
                     <img src="https://static.igem.org/mediawiki/2015/e/e9/Freiburg_DNAonPDMS.png" width="250px">   
 
                     <div class="thumbcaption">
 
                     <div class="thumbcaption">
 
                   </a>
 
                   </a>
                       <p><strong>Figure 2: Immobilization of DNA on a PDMS slide.</strong> A: Top view on the slide indicating the spotting pattern. B: Cy3 fluorescence indicating successful immobilization of amino-labeled DNA. As a negative control, Cy3- but not amino-labeled DNA was spotted.</p>
+
                       <p><strong>Figure 2: Immobilization of DNA on a PDMS slide.</strong> A: Top view on the slide indicating the spotting pattern. B: Cy3 fluorescence showing successful immobilization of amino-labeled DNA. As a negative control, Cy3-labeled DNA without amino group was spotted (indicated by white circles).</p>
 
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                   </div>
 
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<p>
 
<p>
Coupling of DNA to the PDMS slide was achieved using a DNA concentration of 25&nbsp;ng/µl. Either 1 or 3 µl were spotted directly onto the slide using a distinct pattern (figure 2A). To verify that immobilization occurs specifically for amino-labeled DNA, we used non-amino-labeled DNA as a negative control and spotted the same amount. The slide was subsequently incubated over night and the DNA solution was dried afterwards at 60°C. After washing the slide, immobilized DNA was visualized by fluorescence microscopy. The resulting fluorescence pattern clearly corresponds to the spotting pattern on the slide, thereby confirming that the immobilization of DNA was successful. Spots that were incubated with amino-labeled DNA show a distinct Cy3 fluorescence signal, whereas DNA that was not labeled with an amino group was not bound to the surface (figure 2B).  
+
Coupling of DNA to the PDMS slide was achieved using a DNA concentration of 25&nbsp;ng/µl. Either 1 or 3 µl of DNA were spotted directly onto the slide using a distinct pattern (figure 2A). To verify that only the amino-labeled DNA binds specifically, we added spots of non-amino-labeled DNA as a negative control. The slide was subsequently incubated over night and the DNA solution was washed away with ddH<sub>2</sub>O. After drying, examination of the PDMS flow cell at 532 nm by fluorescence microscopy showed the pattern illustrated in figure 2B. The resulting fluorescence pattern clearly corresponds to the spotting pattern on the slide, thereby confirming that the immobilization of DNA was successful. Spots that were incubated with amino-labeled DNA show a distinct Cy3 fluorescence signal, whereas DNA that was not labeled with an amino group had not bound to the surface.  
 
</p>
 
</p>
  
<h2 class="left">Cell-Free Expression of GFP From Spotted DNA</h2>
 
  
<div class="image_box left">
+
<h2>Cell-Free Expression of GFP From DNA Spots</h2>
 +
 
 +
<div class="image_box right">
 
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  <div class="thumb2 trien" style="width:300px">
 
                 <div class="thumbinner">
 
                 <div class="thumbinner">
                     <a href="lightbox_trigger" href="https://static.igem.org/mediawiki/2015/thumb/9/99/Freiburg_20150911_DNA_on_PDMS_7.0_oven30min_expr30min.jpg/794px-Freiburg_20150911_DNA_on_PDMS_7.0_oven30min_expr30min.jpg" class="lightbox_trigger">
+
                     <a href="lightbox_trigger" href="https://static.igem.org/mediawiki/2015/2/2a/Freiburg_DNA_GFP_fluo_2Spots.png" class="lightbox_trigger">
                     <img src="https://static.igem.org/mediawiki/2015/thumb/9/99/Freiburg_20150911_DNA_on_PDMS_7.0_oven30min_expr30min.jpg/794px-Freiburg_20150911_DNA_on_PDMS_7.0_oven30min_expr30min.jpg" width="250px">   
+
                     <img src="https://static.igem.org/mediawiki/2015/2/2a/Freiburg_DNA_GFP_fluo_2Spots.png" width="250px">   
 
                     <div class="thumbcaption">
 
                     <div class="thumbcaption">
 
                   </a>
 
                   </a>
                       <p><strong>Figure 3: GFP expressed from immobilized DNA.</strong> Fluorescence microscopy was used to visualize GFP after expression of immobilized DNA. Expression was performed for 2 h using our DiaMIX and immobilization of the His-tagged GFP was obtained by our Ni-NTA surface.</p>
+
                       <p><strong>Figure 3: Fluorescent GFP spots after 30 min of cell-free expression.</strong> The fluorescence was measured by placing the assembled chamber under a microscope. The system was still filled with expression mix.</p>
 
                   </div>
 
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<p>
 
<p>
In addition to DNA immobilization itself, it is important to show that the immobilized sequence is still capable of being transcribed and translated. Therefore, the sequence was designed to contain all important elements for protein expression as promoter, ribosomal binding site and terminator. Additionally, it was adapted to the requirements of a cell-free expression system.  
+
Having verified that DNA can be bound to the PDMS flow cell, the next step was showing that the immobilized sequence is still capable of being transcribed and translated.
 
<br>
 
<br>
The microfluidic chamber consisting of the PDMS slide and an activated glass slide was assembled after immobilization of a GFP expression cassette. Using the microfluidic system, the DiaCHIP was flushed with our DiaMIX enabling cell-free expression to take place. To achieve a high yield of expressed GFP, the expression was performed for 2 h at room temperature. The glass slide was covered with our specific Ni-NTA surface. Thus, only His-tagged GFP is immobilized on the opposite site of the chamber, while other components of the DiaMIX are washed away after the expression.
+
The microfluidic chamber consisting of the PDMS slide and a glass slide with a specific Ni-NTA surface was then assembled and filled with cell-free expression mix. The expression was performed for 2 h at 37°C.  
 
<br>
 
<br>
The glass slide was analyzed by fluorescence microscopy afterwards. As it is shown in figure 3, cell-free expressed GFP was imobilized in distinct spots and exhibited a fluorescence signal. Thus, besides being expressed, the protein was also correctly folded and remains functional.  
+
The microfluidic chamber was analyzed by fluorescence microscopy afterwards. As shown in figure 3, cell-free expressed GFP was observed in distinct spots exhibiting a clear fluorescence signal. Thus, besides being expressed, the protein was also correctly folded and remained functional.
 +
</p>
 +
 
 +
 
 +
<h2>Putting it All Together</h2>
 +
 
 +
<p>So far, we have shown that we are able to effect the different steps of the DiaCHIP system independently from each other.  
 
</p>
 
</p>
  
 
<p>
 
<p>
<h3>All in all, we showed that:</h3>
+
<ul>
<ol>
+
    <li>DNA can be immobilized reliably on a self-prepared PDMS surface using an amino-label.</li>
<li>DNA can be immobilized reliably on a PDMS surface using an amino-label.</li>
+
    <li>Our DNA sequences are capable of being expressed even when being bound to a surface.</li>
<li>our DNA sequences are capable of being expressed by the DiaMIX although being immobilized.</li>
+
    <li>The expressed protein stays fully functional.</li>
<li>the DiaMIX succeeds in the expression fully funtional GFP.</li>
+
</ul>
</ol>
+
 
</p>
 
</p>
 +
 +
<p>
 +
In consequence of these results, we combined all the single steps in one experiment. Therefore, DNA coding for His-GFP was immobilized on two PDMS flow cells. The microfluidic chambers were assembled by covering the flow cells with Ni-NTA coated glass slides. Cell-free expression was conducted with our DiaMIX and a commercial expression kit based on rabbit reticulocytes. The expression using the DiaMIX was performed at 37°C for 2&nbsp;h, while the commercial kit was incubated at 30°C for 90&nbsp;min. After expression, both slides were washed with PBS and stored at 4°C for a few hours. To examine if His-GFP was expressed and immobilized on the Ni-NTA successfully, the slides were measured in iRIf. The slides were first blocked with 10&nbsp;mg/mL BSA using the microfluidic system, then anti-GFP was flushed over. Figures 4 and 5 show the binding curves we obtained from these two experiments.
 +
</p>
 +
 +
 +
<div class="image_box left">
 +
<div class="thumb2 trien" style="width:410px">
 +
                <div class="thumbinner">
 +
                    <a href="https://static.igem.org/mediawiki/2015/1/12/Freiburg_expression_in_flow_cell_with_DiaMIX_binding_curve.png" class="lightbox_trigger">
 +
                    <img src="https://static.igem.org/mediawiki/2015/1/12/Freiburg_expression_in_flow_cell_with_DiaMIX_binding_curve.png" width="400px"> 
 +
                    <div class="thumbcaption">
 +
                  </a>
 +
                      <p><strong>Figure 4: Binding curve of iRIf measurement after cell-free expression of His-GFP in flow chamber with the DiaMIX.</strong>The graph shows a slight change in relative intensity at one spot of cell-free expressed GFP when anti-GFP was flushes over.</p>
 +
                  </div>
 +
              </div>
 +
</div>
 +
</div>
 +
 +
<div class="image_box right">
 +
<div class="thumb2 trien" style="width:427px">
 +
                <div class="thumbinner">
 +
                    <a href="https://static.igem.org/mediawiki/2015/7/71/Freiburg_expression_in_flow_cell_with_reticulocytes_binding_curve.png" class="lightbox_trigger">
 +
                    <img src="https://static.igem.org/mediawiki/2015/7/71/Freiburg_expression_in_flow_cell_with_reticulocytes_binding_curve.png" width="417px"> 
 +
                    <div class="thumbcaption">
 +
                  </a>
 +
                      <p><strong>Figure 5: Binding curve of iRIf measurement after cell-free expression of His-GFP in flow chamber with the commercial kit.</strong>The graph shows a slight change in relative intensity at one spot of cell-free expressed GFP when anti-GFP was flushes over.</p>
 +
                  </div>
 +
              </div>
 +
</div>
 +
</div>
 +
 +
<br style="clear:both">
 +
<p>
 +
<br>
 +
<br>
 +
Although the relative intensity change is quite low, an increased signal at the spots where the GFP should have bound after diffusion can be observed. Due to the low signal increase during anti-GFP binding clear quotient pictues cannot be produced. The intensity change is in a comparable range for both expression mixes. This indicates that the expression of His-GFP as well as its diffusion and specific binding to the opposite slide was successful.
 +
<br>
 +
Nonetheless, the experiment should be repeated, as the signal was not far above the background. Unfortunately, we did not have the time to reproduce and validate this result. Assuming that this result is reproducible, still a lot of optimization is necessary to obtain higher yields of protein expression. Consequently, higher signals in iRIf due to more specific antibody binding sites on the surface would be achieved.
 +
</p>
 +
<p>
 +
This experiment underlines the potential of the DiaCHIP for future applications. It reveals that our DiaCHIP system is capable of producing protein microarrays on demand and detect antibodies by their binding to the corresponding antigens on the surface.
 +
</p>
 +
 +
  
 
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Latest revision as of 01:56, 19 September 2015

""

Cell-Free Expression of Immobilized DNA

An important advantage of the DiaCHIP is the possibility to ship and store information encoded by DNA. From a DNA template array protein arrays can be produced on demand. As DNA is far more resistant to diverse cues e.g. temperature. In order to obtain this template, DNA is fixed on a silicone slide forming one side of our microfluidic chamber. Making use of a cell-free expression system, the DNA can then be transcribed and translated into the encoded proteins resulting in the final protein array. The coding sequence of the proteins is genetically fused to a tag allowing their binding to a specific surface on the opposite side of the chamber.

Successful binding of DNA to the Silicone Slide

Figure 1: Scheme of the APTES/PDITC surface. The PDMS (red) is layered with APTES (light grey) and the amino-linker PDITC (dark grey). The hydroxy layer generated during plasma activation is represented in blue.

The core component of the DiaCHIP is the microfluidic chamber composed of a glass slide for protein immobilization and a PDMS (polydimethylsiloxane) flow cell. The silicone PDMS needs to be activated to enable the generation of the DNA template array by binding of the respective sequences. Oxygen plasma is used to initially activate the surface of the PDMS slide by generating a hydroxy layer. This allows linking the silane APTES and subsequently the crosslinker PDITC. In order to bind the DNA covalently to this surface the respective DNA sequence requires an N- or C-terminal amino group. The structure of this surface is schematically visualized in figure 1. This surface chemistry is identical to the protocol used to immobilize proteins on a glass slide unspecifically (see PDITC surface for immobilizing proteins).
In order to obtain an expression cassette for GFP with an amino group, the target sequence was amplified by PCR using an amino-labeled reverse primer. Additionally, the forward primer was labeled by the fluorescent dye Cy3 to enable visualization by fluorescence microscopy. Successful amplification of the target sequence was verified by agarose gel electrophoresis.

Figure 2: Immobilization of DNA on a PDMS slide. A: Top view on the slide indicating the spotting pattern. B: Cy3 fluorescence showing successful immobilization of amino-labeled DNA. As a negative control, Cy3-labeled DNA without amino group was spotted (indicated by white circles).

Coupling of DNA to the PDMS slide was achieved using a DNA concentration of 25 ng/µl. Either 1 or 3 µl of DNA were spotted directly onto the slide using a distinct pattern (figure 2A). To verify that only the amino-labeled DNA binds specifically, we added spots of non-amino-labeled DNA as a negative control. The slide was subsequently incubated over night and the DNA solution was washed away with ddH2O. After drying, examination of the PDMS flow cell at 532 nm by fluorescence microscopy showed the pattern illustrated in figure 2B. The resulting fluorescence pattern clearly corresponds to the spotting pattern on the slide, thereby confirming that the immobilization of DNA was successful. Spots that were incubated with amino-labeled DNA show a distinct Cy3 fluorescence signal, whereas DNA that was not labeled with an amino group had not bound to the surface.

Cell-Free Expression of GFP From DNA Spots

Figure 3: Fluorescent GFP spots after 30 min of cell-free expression. The fluorescence was measured by placing the assembled chamber under a microscope. The system was still filled with expression mix.

Having verified that DNA can be bound to the PDMS flow cell, the next step was showing that the immobilized sequence is still capable of being transcribed and translated.
The microfluidic chamber consisting of the PDMS slide and a glass slide with a specific Ni-NTA surface was then assembled and filled with cell-free expression mix. The expression was performed for 2 h at 37°C.
The microfluidic chamber was analyzed by fluorescence microscopy afterwards. As shown in figure 3, cell-free expressed GFP was observed in distinct spots exhibiting a clear fluorescence signal. Thus, besides being expressed, the protein was also correctly folded and remained functional.

Putting it All Together

So far, we have shown that we are able to effect the different steps of the DiaCHIP system independently from each other.

  • DNA can be immobilized reliably on a self-prepared PDMS surface using an amino-label.
  • Our DNA sequences are capable of being expressed even when being bound to a surface.
  • The expressed protein stays fully functional.

In consequence of these results, we combined all the single steps in one experiment. Therefore, DNA coding for His-GFP was immobilized on two PDMS flow cells. The microfluidic chambers were assembled by covering the flow cells with Ni-NTA coated glass slides. Cell-free expression was conducted with our DiaMIX and a commercial expression kit based on rabbit reticulocytes. The expression using the DiaMIX was performed at 37°C for 2 h, while the commercial kit was incubated at 30°C for 90 min. After expression, both slides were washed with PBS and stored at 4°C for a few hours. To examine if His-GFP was expressed and immobilized on the Ni-NTA successfully, the slides were measured in iRIf. The slides were first blocked with 10 mg/mL BSA using the microfluidic system, then anti-GFP was flushed over. Figures 4 and 5 show the binding curves we obtained from these two experiments.

Figure 4: Binding curve of iRIf measurement after cell-free expression of His-GFP in flow chamber with the DiaMIX.The graph shows a slight change in relative intensity at one spot of cell-free expressed GFP when anti-GFP was flushes over.

Figure 5: Binding curve of iRIf measurement after cell-free expression of His-GFP in flow chamber with the commercial kit.The graph shows a slight change in relative intensity at one spot of cell-free expressed GFP when anti-GFP was flushes over.




Although the relative intensity change is quite low, an increased signal at the spots where the GFP should have bound after diffusion can be observed. Due to the low signal increase during anti-GFP binding clear quotient pictues cannot be produced. The intensity change is in a comparable range for both expression mixes. This indicates that the expression of His-GFP as well as its diffusion and specific binding to the opposite slide was successful.
Nonetheless, the experiment should be repeated, as the signal was not far above the background. Unfortunately, we did not have the time to reproduce and validate this result. Assuming that this result is reproducible, still a lot of optimization is necessary to obtain higher yields of protein expression. Consequently, higher signals in iRIf due to more specific antibody binding sites on the surface would be achieved.

This experiment underlines the potential of the DiaCHIP for future applications. It reveals that our DiaCHIP system is capable of producing protein microarrays on demand and detect antibodies by their binding to the corresponding antigens on the surface.