Difference between revisions of "Team:BNU-China/Protocol"

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<html>
 
<html>
<div class="main-container">
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<div class="main-container">
<div id="page-heading" class="container-fluid page-heading"
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    <div id="page-heading" class="container-fluid page-heading"
style="background-image: url(https://static.igem.org/mediawiki/2016/9/96/T--BNU-China--team.jpg);">
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        style="background-image: url(https://static.igem.org/mediawiki/2016/9/96/T--BNU-China--team.jpg);">
<h3> PROTOCOL </h3>
+
        <h3> PROTOCOL </h3>
</div>
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    </div>
<div style="background-image: url(https://static.igem.org/mediawiki/2016/e/e5/T--BNU-China--landingImage.jpg); background-size: 100%;">
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    <div style="background-image: url(https://static.igem.org/mediawiki/2016/e/e5/T--BNU-China--landingImage.jpg); background-size: 100%;">
<div class="container page-story">
+
        <div class="container page-story">
<article id="modeling"
+
            <article id="modeling"
class="col-lg-10 col-lg-offset-1 col-md-12 col-md-offset-0 col-sm-offset-0 col-sm-12">
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                    class="col-lg-10 col-lg-offset-1 col-md-12 col-md-offset-0 col-sm-offset-0 col-sm-12">
<header class="page-header">
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                <header class="page-header">
<h1>Protocol</h1>
+
                    <h1>Protocol</h1>
<small id="secondary-page-header">This is our Modeling Design</small>
+
                    <small id="secondary-page-header">This is our Modeling Design</small>
</header>
+
                </header>
<h2>Cloning</h2>
+
                <h2>Cloning</h2>
<h3>PCR</h3>
+
                <h3>PCR</h3>
<h4>Reaction system:</h4>
+
                <h4>Reaction system:</h4>
<br/>
+
                <br/>
<h5>1. </h5>
+
                <h5>1. </h5>
<p>\(H_2 O\ \ 2\mu L\)</p>
+
                <p>\(H_2 O\ \ 2\mu L\)</p>
<p>\(10\mathrm{x}\ \ Taq \ \ buffer \ \ 5\mu\mathrm{L}\)</p>
+
                <p>\(10\mathrm{x}\ \ Taq \ \ buffer \ \ 5\mu\mathrm{L}\)</p>
<p>\(2.5mM \ \ dNTP \ \ 1\mu\mathrm{L}\)</p>
+
                <p>\(2.5mM \ \ dNTP \ \ 1\mu\mathrm{L}\)</p>
<p>\(R+F-Primer \ \ 10\mu\mathrm{L}\)</p>
+
                <p>\(R+F-Primer \ \ 10\mu\mathrm{L}\)</p>
<p>\(Template \ \ 10\mu\mathrm{L}\)</p>
+
                <p>\(Template \ \ 10\mu\mathrm{L}\)</p>
<p>\(Taq \ \ 2.5\mu\mathrm{L}\)</p>
+
                <p>\(Taq \ \ 2.5\mu\mathrm{L}\)</p>
<p>\(Universal \ \ DNA \ \ polymerase \ \ TransGen\)</p>
+
                <p>\(Universal \ \ DNA \ \ polymerase \ \ TransGen\)</p>
<br/>
+
                <br/>
<h5>2. </h5>
+
                <h5>2. </h5>
<p>\(H_2 O\ \ 20\mu\mathrm{L}\)</p>
+
                <p>\(H_2 O\ \ 20\mu\mathrm{L}\)</p>
<p>\(5\mathrm{x}\ \ Taq\ \ buffer\ \ 10\mu\mathrm{L}\)</p>
+
                <p>\(5\mathrm{x}\ \ Taq\ \ buffer\ \ 10\mu\mathrm{L}\)</p>
<p>\(2.5mM\ \ dNTP\ \ 5\mu\mathrm{L}\)</p>
+
                <p>\(2.5mM\ \ dNTP\ \ 5\mu\mathrm{L}\)</p>
<p>\(R+F-Primer\ \ 44\mu\mathrm{L}\)</p>
+
                <p>\(R+F-Primer\ \ 44\mu\mathrm{L}\)</p>
<p>\(Template\ \ 10\mu\mathrm{L}\)</p>
+
                <p>\(Template\ \ 10\mu\mathrm{L}\)</p>
<p>\(Taq\ \ 1\mu\mathrm{L}\)</p>
+
                <p>\(Taq\ \ 1\mu\mathrm{L}\)</p>
<br/>
+
                <br/>
<h5>3. </h5>
+
                <h5>3. </h5>
<p>\(primeSTAR\ \ from\ \ Takara\)</p>
+
                <p>\(primeSTAR\ \ from\ \ Takara\)</p>
<p>\(H_2 O\ \ 21\mu\mathrm{L}\)</p>
+
                <p>\(H_2 O\ \ 21\mu\mathrm{L}\)</p>
<p>\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)</p>
+
                <p>\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)</p>
<p>\(R+F-Primer\ \ 2\mu\mathrm{L}\)</p>
+
                <p>\(R+F-Primer\ \ 2\mu\mathrm{L}\)</p>
<p>\(Template\ \ 2\mu\mathrm{L}\)</p>
+
                <p>\(Template\ \ 2\mu\mathrm{L}\)</p>
<h4>Process:</h4>
+
                <h4>Process:</h4>
<p>98&#176;C 2min </p>
+
                <p>98&#176;C 2min </p>
<p> \( \begin{equation} \left. \begin{array}{lcl} {98&#176;C\ 10s} \\ {56&#176;C\ 15s} \\{72&#176;C\
+
                <p> \( \begin{equation} \left. \begin{array}{lcl} {98&#176;C\ 10s} \\ {56&#176;C\ 15s} \\{72&#176;C\
30s} \end{array} \right \} Cycle\ 35 \end{equation} \) </p>
+
                    30s} \end{array} \right \} Cycle\ 35 \end{equation} \) </p>
<p>72&#176;C 5min </p>
+
                <p>72&#176;C 5min </p>
<p>4&#176;C --- </p>
+
                <p>4&#176;C --- </p>
<p>98&#176;C 2min </p>
+
                <p>98&#176;C 2min </p>
<p>\(\begin{equation}\left. \begin{array}{lcl} {98&#176;C\ 10s} \\ {55&#176;C\ 5s} \\{72&#176;C\ 8s}
+
                <p>\(\begin{equation}\left. \begin{array}{lcl} {98&#176;C\ 10s} \\ {55&#176;C\ 5s} \\{72&#176;C\ 8s}
\end{array} \right\}Cycle\ 35\end{equation}\)</p>
+
                    \end{array} \right\}Cycle\ 35\end{equation}\)</p>
<p>72&#176;C 5min </p>
+
                <p>72&#176;C 5min </p>
<p>15&#176;C --- </p>
+
                <p>15&#176;C --- </p>
<h5>Fusion PCR:</h5>
+
                <h5>Fusion PCR:</h5>
<ol>
+
                <ol>
<li> basic PCR</li>
+
                    <li> basic PCR</li>
<li> using the PCR product of step 1 as template does PCR</li>
+
                    <li> using the PCR product of step 1 as template does PCR</li>
<li> using the PCR product of step 2 as template does PCR,but first five cycles don’t add primer,
+
                    <li> using the PCR product of step 2 as template does PCR,but first five cycles don’t add primer,
after first five cycles, the sixth cycle adds primer and continue PCR.
+
                        after first five cycles, the sixth cycle adds primer and continue PCR.
</li>
+
                    </li>
</ol>
+
                </ol>
<h5> The system of step 2: </h5>
+
                <h5> The system of step 2: </h5>
<p>\(H_2 O\ \ 21\mu\mathrm{L}\)</p>
+
                <p>\(H_2 O\ \ 21\mu\mathrm{L}\)</p>
<p>\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)</p>
+
                <p>\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)</p>
<p>\(R+F-Primer\ \ 2\mu\mathrm{L}\)</p>
+
                <p>\(R+F-Primer\ \ 2\mu\mathrm{L}\)</p>
<p>\(Template①\ \ 1\mu\mathrm{L}\)</p>
+
                <p>\(Template①\ \ 1\mu\mathrm{L}\)</p>
<p>\(Template②\ \ 1\mu\mathrm{L}\)</p>
+
                <p>\(Template②\ \ 1\mu\mathrm{L}\)</p>
  
<h3>Electrophoresis---Gel Purification</h3>
+
                <h3>Electrophoresis---Gel Purification</h3>
<h4>Material:</h4>
+
                <h4>Material:</h4>
<p>Agarose gel: 1% agarose dissolved in 1 x TAE + gelstain</p>
+
                <p>Agarose gel: 1% agarose dissolved in 1 x TAE + gelstain</p>
<h4>Protocol:</h4>
+
                <h4>Protocol:</h4>
<p>We used gelstain to stain the DNA and imaged it in a Transilluminator.</p>
+
                <p>We used gelstain to stain the DNA and imaged it in a Transilluminator.</p>
<p>We used the gel extraction kit to get the objective fragment.</p>
+
                <p>We used the gel extraction kit to get the objective fragment.</p>
<p>We used the DNA fragment purification kit to get the objective fragment.</p>
+
                <p>We used the DNA fragment purification kit to get the objective fragment.</p>
<h3>Digestion</h3>
+
                <h3>Digestion</h3>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="6" style="text-align: center">\(50\mu\mathrm{L} \ \ \mathrm{reaction \ \
+
                        <th colspan="6" style="text-align: center">\(50\mu\mathrm{L} \ \ \mathrm{reaction \ \
system}\)
+
                            system}\)
</th>
+
                        </th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">10x \(\ \mathrm{H \ buffer}\)</td>
+
                        <td align="center">10x \(\ \mathrm{H \ buffer}\)</td>
<td align="center">\(Eco\mathrm{R}\ \mathrm{I}\)</td>
+
                        <td align="center">\(Eco\mathrm{R}\ \mathrm{I}\)</td>
<td align="center">\(Pat\ \mathrm{I}\)</td>
+
                        <td align="center">\(Pat\ \mathrm{I}\)</td>
<td align="center">\(\mathrm{Plasmid}\)</td>
+
                        <td align="center">\(\mathrm{Plasmid}\)</td>
<td align="center">\(\mathrm{H_2 O}\)</td>
+
                        <td align="center">\(\mathrm{H_2 O}\)</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">\(5\mu\mathrm{L}\)</td>
+
                        <td align="center">\(5\mu\mathrm{L}\)</td>
<td align="center">\(1.5\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1.5\mu\mathrm{L}\)</td>
<td align="center">\(1.5\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1.5\mu\mathrm{L}\)</td>
<td align="center">\(15\mu\mathrm{L}\)</td>
+
                        <td align="center">\(15\mu\mathrm{L}\)</td>
<td align="center">\(27\mu\mathrm{L}\)</td>
+
                        <td align="center">\(27\mu\mathrm{L}\)</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<th colspan="6" style="text-align: center">\(10\mu\mathrm{L} \ \ \mathrm{reaction \ \
+
                        <th colspan="6" style="text-align: center">\(10\mu\mathrm{L} \ \ \mathrm{reaction \ \
system}\)
+
                            system}\)
</th>
+
                        </th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">10x \(\ \mathrm{H \ buffer}\)</td>
+
                        <td align="center">10x \(\ \mathrm{H \ buffer}\)</td>
<td align="center">\(Eco\mathrm{R}\ \mathrm{I}\)</td>
+
                        <td align="center">\(Eco\mathrm{R}\ \mathrm{I}\)</td>
<td align="center">\(Pat\ \mathrm{I}\)</td>
+
                        <td align="center">\(Pat\ \mathrm{I}\)</td>
<td align="center">\(\mathrm{Plasmid}\)</td>
+
                        <td align="center">\(\mathrm{Plasmid}\)</td>
<td align="center">\(\mathrm{H_2 O}\)</td>
+
                        <td align="center">\(\mathrm{H_2 O}\)</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">\(1\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1\mu\mathrm{L}\)</td>
<td align="center">\(0.3\mu\mathrm{L}\)</td>
+
                        <td align="center">\(0.3\mu\mathrm{L}\)</td>
<td align="center">\(0.3\mu\mathrm{L}\)</td>
+
                        <td align="center">\(0.3\mu\mathrm{L}\)</td>
<td align="center">\(3\mu\mathrm{L}\)</td>
+
                        <td align="center">\(3\mu\mathrm{L}\)</td>
<td align="center">\(5.4\mu\mathrm{L}\)</td>
+
                        <td align="center">\(5.4\mu\mathrm{L}\)</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<h2>Ligation</h2>
+
                <h2>Ligation</h2>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="5" style="text-align: center">Ligation reaction system</th>
+
                        <th colspan="5" style="text-align: center">Ligation reaction system</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">DNA</td>
+
                        <td align="center">DNA</td>
<td align="center">Plasmid</td>
+
                        <td align="center">Plasmid</td>
<td align="center">T4 buffer</td>
+
                        <td align="center">T4 buffer</td>
<td align="center">T4 ligase</td>
+
                        <td align="center">T4 ligase</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">\(7\mu\mathrm{L}\)</td>
+
                        <td align="center">\(7\mu\mathrm{L}\)</td>
<td align="center">\(1\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1\mu\mathrm{L}\)</td>
<td align="center">\(1\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1\mu\mathrm{L}\)</td>
<td align="center">\(1\mu\mathrm{L}\)</td>
+
                        <td align="center">\(1\mu\mathrm{L}\)</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<h3>LR reaction</h3>
+
                <h3>LR reaction</h3>
  
<h4>1. Entry linearization</h4>
+
                <h4>1. Entry linearization</h4>
<p>β2-TOPO(plasmid concentration 117ng/μL) NotI 37&#176;C enzyme digestion for the night</p>
+
                <p>β2-TOPO(plasmid concentration 117ng/μL) NotI 37&#176;C enzyme digestion for the night</p>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="2"> 50μL Single enzyme system</th>
+
                        <th style="text-align: center" colspan="2"> 50μL Single enzyme system</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">10x BufferH</td>
+
                        <td align="center">10x BufferH</td>
<td align="center">5μL</td>
+
                        <td align="center">5μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">DNA</td>
+
                        <td align="center">DNA</td>
<td align="center">20μL</td>
+
                        <td align="center">20μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">ddH<sub>2</sub>O</td>
+
                        <td align="center">ddH<sub>2</sub>O</td>
<td align="center">12.5μL</td>
+
                        <td align="center">12.5μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Enzyme</td>
+
                        <td align="center">Enzyme</td>
<td align="center">2.5μL</td>
+
                        <td align="center">2.5μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">0.1%BSA</td>
+
                        <td align="center">0.1%BSA</td>
<td align="center">5μL</td>
+
                        <td align="center">5μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">0.1%Triton X-100</td>
+
                        <td align="center">0.1%Triton X-100</td>
<td align="center">5μL</td>
+
                        <td align="center">5μL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<h4>2. LR system (\(4\mu\mathrm{L}\)):</h4>
+
                <h4>2. LR system (\(4\mu\mathrm{L}\)):</h4>
<p>100 ng/ul linear Entry: 0.5 ul</p>
+
                <p>100 ng/ul linear Entry: 0.5 ul</p>
<p>destination vector: 1 ul (pCambia1300-nluc / pCambia1300-cluceach one)</p>
+
                <p>destination vector: 1 ul (pCambia1300-nluc / pCambia1300-cluceach one)</p>
<p>LR Clonase II enzyme mix: 1 ul</p>
+
                <p>LR Clonase II enzyme mix: 1 ul</p>
<p>ddH2O: 0.5 ul</p>
+
                <p>ddH2O: 0.5 ul</p>
<p>mix slightly,water base for 5 h at 25&#176;C </p>
+
                <p>mix slightly,water base for 5 h at 25&#176;C </p>
<p>transform, 4 ul, reactant transform 50 ul competent cells</p>
+
                <p>transform, 4 ul, reactant transform 50 ul competent cells</p>
  
<h2>Transformation</h2>
+
                <h2>Transformation</h2>
  
<h3>Material:</h3>
+
                <h3>Material:</h3>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="4" style="text-align: center">LB liquid medium</th>
+
                        <th colspan="4" style="text-align: center">LB liquid medium</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">Tryptone</td>
+
                        <td align="center">Tryptone</td>
<td align="center">Yeast extract powder</td>
+
                        <td align="center">Yeast extract powder</td>
<td align="center">NaCl</td>
+
                        <td align="center">NaCl</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">10 g/L</td>
+
                        <td align="center">10 g/L</td>
<td align="center">5 g/L</td>
+
                        <td align="center">5 g/L</td>
<td align="center">10 μL</td>
+
                        <td align="center">10 μL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<h3>Protocol:</h3>
+
                <h3>Protocol:</h3>
<p> preparation of the competent cells </p>
+
                <p> preparation of the competent cells </p>
<p> 1μL ligation product + 50μL cells </p>
+
                <p> 1μL ligation product + 50μL cells </p>
<p>Heatshock of Trans5α(42&#176;C,45s)</p>
+
                <p>Heatshock of Trans5α(42&#176;C,45s)</p>
<p>Put on ice(2min)</p>
+
                <p>Put on ice(2min)</p>
<p>Add 500μL LB media and incubate for 1h(37&#176;C, 150rpm)</p>
+
                <p>Add 500μL LB media and incubate for 1h(37&#176;C, 150rpm)</p>
<p>Centrifuge at 4000rpm for 1min and remove 400μL supernatant</p>
+
                <p>Centrifuge at 4000rpm for 1min and remove 400μL supernatant</p>
<p>Resuspend the pellets using the left supernatant</p>
+
                <p>Resuspend the pellets using the left supernatant</p>
<p>Spread plates(with Kan;CHL)</p>
+
                <p>Spread plates(with Kan;CHL)</p>
<p>Incubate for 12~16h(37&#176;C)</p>
+
                <p>Incubate for 12~16h(37&#176;C)</p>
  
<h2>Protein Expression</h2>
+
                <h2>Protein Expression</h2>
<ol>
+
                <ol>
<li>Inoculated 3 mL LB media including relevant antibiotics with the monoclonal colony of expression plasmid, incubate for 12~16h(37&#176;C, 190rpm)</li>
+
                    <li>Inoculated 3 mL LB media including relevant antibiotics with the monoclonal colony of expression
<li>Inoculated 100 mL TM expression media including relevant antibiotics with the 1mL bacteria liquid, incubate for 3h(37&#176;C, 250rpm,OD600=0.6~0.8)</li>
+
                        plasmid, incubate for 12~16h(37&#176;C, 190rpm)
<li>Add IPTG into it until its final concentration is 1mmol/L, incubate for 4~6h(37&#176;C, 250rpm)</li>
+
                    </li>
<li>Centrifuge at 6000rpm for 10min and remove supernatant</li>
+
                    <li>Inoculated 100 mL TM expression media including relevant antibiotics with the 1mL bacteria
<li>Gather sediment, cryopreserve at -20&#176;C</li>
+
                        liquid, incubate for 3h(37&#176;C, 250rpm,OD600=0.6~0.8)
</ol>
+
                    </li>
<p>Material:</p>
+
                    <li>Add IPTG into it until its final concentration is 1mmol/L, incubate for 4~6h(37&#176;C,
<p>TM expression medium:1000mL PH=7.4</p>
+
                        250rpm)
 +
                    </li>
 +
                    <li>Centrifuge at 6000rpm for 10min and remove supernatant</li>
 +
                    <li>Gather sediment, cryopreserve at -20&#176;C</li>
 +
                </ol>
 +
                <p>Material:</p>
 +
                <p>TM expression medium:1000mL PH=7.4</p>
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">tryptone</td>
+
                        <td align="center">tryptone</td>
<td align="center">Yeast extract powder</td>
+
                        <td align="center">Yeast extract powder</td>
<td align="center">NaCl </td>
+
                        <td align="center">NaCl</td>
<td align="center">glucose </td>
+
                        <td align="center">glucose</td>
<td align="center">glycerol</td>
+
                        <td align="center">glycerol</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">1.2g</td>
+
                        <td align="center">1.2g</td>
<td align="center">2.4g</td>
+
                        <td align="center">2.4g</td>
<td align="center">1.0g</td>
+
                        <td align="center">1.0g</td>
<td align="center">1.0g</td>
+
                        <td align="center">1.0g</td>
<td align="center">0.6mL</td>
+
                        <td align="center">0.6mL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
<p>Autoclaving 115℃,20min</p>
+
                <p>Autoclaving 115℃,20min</p>
  
<h2>Detetion</h2>
+
                <h2>Detetion</h2>
<h3>SDS-PAGE</h3>
+
                <h3>SDS-PAGE</h3>
<h4>Materials</h4>
+
                <h4>Materials</h4>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center">Gel</th>
+
                        <th style="text-align: center">Gel</th>
<th style="text-align: center">Tris-HCl</th>
+
                        <th style="text-align: center">Tris-HCl</th>
<th style="text-align: center">Acr/Bis 30% </th>
+
                        <th style="text-align: center">Acr/Bis 30%</th>
<th style="text-align: center">SDS 10% </th>
+
                        <th style="text-align: center">SDS 10%</th>
<th style="text-align: center">ddH2O</th>
+
                        <th style="text-align: center">ddH2O</th>
<th style="text-align: center">TEMED </th>
+
                        <th style="text-align: center">TEMED</th>
<th style="text-align: center">AP 10% </th>
+
                        <th style="text-align: center">AP 10%</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Stacking Gel(4%) </td>
+
                        <td align="center">Stacking Gel(4%)</td>
<td align="center">pH=6.8 500μL </td>
+
                        <td align="center">pH=6.8 500μL</td>
<td align="center">500 μL</td>
+
                        <td align="center">500 μL</td>
<td align="center">25 μL</td>
+
                        <td align="center">25 μL</td>
<td align="center">1350μL</td>
+
                        <td align="center">1350μL</td>
<td align="center">2.5μL</td>
+
                        <td align="center">2.5μL</td>
<td align="center">12.5μL</td>
+
                        <td align="center">12.5μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Running Gel(12%) </td>
+
                        <td align="center">Running Gel(12%)</td>
<td align="center">pH=8.8 1250μL</td>
+
                        <td align="center">pH=8.8 1250μL</td>
<td align="center">2000 μL</td>
+
                        <td align="center">2000 μL</td>
<td align="center">50 μL</td>
+
                        <td align="center">50 μL</td>
<td align="center">1675μL</td>
+
                        <td align="center">1675μL</td>
<td align="center">2.5μL</td>
+
                        <td align="center">2.5μL</td>
<td align="center">25 μL</td>
+
                        <td align="center">25 μL</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Running Gel(18%) </td>
+
                        <td align="center">Running Gel(18%)</td>
<td align="center">pH=8.8 1250μL</td>
+
                        <td align="center">pH=8.8 1250μL</td>
<td align="center">3000 μL</td>
+
                        <td align="center">3000 μL</td>
<td align="center">50 μL</td>
+
                        <td align="center">50 μL</td>
<td align="center">675 μL</td>
+
                        <td align="center">675 μL</td>
<td align="center">2.5μL</td>
+
                        <td align="center">2.5μL</td>
<td align="center">25 μL</td>
+
                        <td align="center">25 μL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="4" style="text-align: center">Running Buffer</th>
+
                        <th colspan="4" style="text-align: center">Running Buffer</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">Tris-HCl</td>
+
                        <td align="center">Tris-HCl</td>
<td align="center">Glycine</td>
+
                        <td align="center">Glycine</td>
<td align="center">(w/v) SDS</td>
+
                        <td align="center">(w/v) SDS</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">25 mmol/L</td>
+
                        <td align="center">25 mmol/L</td>
<td align="center">0.192 mol/L</td>
+
                        <td align="center">0.192 mol/L</td>
<td align="center">0.1%</td>
+
                        <td align="center">0.1%</td>
</tr>
+
                    </tr>
</table>
+
                </table>
<h4>Protocol</h4>
+
                <h4>Protocol</h4>
<p>The SDS polyacrylamide gels are prepared in the so-called PerfectBlue™ Twin Double Gel System.</p>
+
                <p>The SDS polyacrylamide gels are prepared in the so-called PerfectBlue™ Twin Double Gel System.</p>
<p>After ensuring that the equipment is waterproof, the 12 % (or 18%) running gel is mixed and filled into the chamber. Pipetting about 1 ml of H2O on top of the running gel to seal the gel. </p>
+
                <p>After ensuring that the equipment is waterproof, the 12 % (or 18%) running gel is mixed and filled
<p>After polymerization, the remaining H2O is removed and the 12 % stacking gel is filled on top. Insert a comb to create sample pockets.</p>
+
                    into the chamber. Pipetting about 1 ml of H2O on top of the running gel to seal the gel. </p>
<p>After the stacking gel also polymerized, 1 x running buffer is used to run the Double Gel System via the SDS gel. </p>
+
                <p>After polymerization, the remaining H2O is removed and the 12 % stacking gel is filled on top. Insert
<p>After loading the generated pockets with the samples, the stacking gel is run at 100 V and then running gel at 120 V. </p>
+
                    a comb to create sample pockets.</p>
 +
                <p>After the stacking gel also polymerized, 1 x running buffer is used to run the Double Gel System via
 +
                    the SDS gel. </p>
 +
                <p>After loading the generated pockets with the samples, the stacking gel is run at 100 V and then
 +
                    running gel at 120 V. </p>
  
<h3>Western Blot</h3>
+
                <h3>Western Blot</h3>
<h4>System</h4>
+
                <h4>System</h4>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="6" style="text-align: center"> PBST:1000mL(PH=7.4) </th>
+
                        <th colspan="6" style="text-align: center"> PBST:1000mL(PH=7.4)</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">NaCl(137mM)</td>
+
                        <td align="center">NaCl(137mM)</td>
<td align="center">KCl(2.7mM)</td>
+
                        <td align="center">KCl(2.7mM)</td>
<td align="center">Na2HPO4(10mM)</td>
+
                        <td align="center">Na2HPO4(10mM)</td>
<td align="center">K2HPO4(2mM)</td>
+
                        <td align="center">K2HPO4(2mM)</td>
<td align="center">Tween-20</td>
+
                        <td align="center">Tween-20</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">8g</td>
+
                        <td align="center">8g</td>
<td align="center">0.2g</td>
+
                        <td align="center">0.2g</td>
<td align="center">1.44g</td>
+
                        <td align="center">1.44g</td>
<td align="center">0.24g</td>
+
                        <td align="center">0.24g</td>
<td align="center">0.5mL</td>
+
                        <td align="center">0.5mL</td>
</tr>
+
                    </tr>
  
</table>
+
                </table>
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th colspan="4" style="text-align: center">Imprint buffer:2000mL (PH=8.3) Transfer Buffer</th>
+
                        <th colspan="4" style="text-align: center">Imprint buffer:2000mL (PH=8.3) Transfer Buffer</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">Tris</td>
+
                        <td align="center">Tris</td>
<td align="center">Gly</td>
+
                        <td align="center">Gly</td>
<td align="center">Methanol</td>
+
                        <td align="center">Methanol</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">6.06g</td>
+
                        <td align="center">6.06g</td>
<td align="center">28.8g</td>
+
                        <td align="center">28.8g</td>
<td align="center">400mL</td>
+
                        <td align="center">400mL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<h4>Protocol</h4>
+
                <h4>Protocol</h4>
<p>Transfer (Prepare transfer Buffer just before glue leaking, and precool at -20℃).</p>
+
                <p>Transfer (Prepare transfer Buffer just before glue leaking, and precool at -20℃).</p>
<ol>
+
                <ol>
<li>Put the transfer Buffer and the black subface of transfer splint downword, and lay a sponge in it. Several filter paper(three pieces of filter paper), glue(except Stacking Gel).</li>
+
                    <li>Put the transfer Buffer and the black subface of transfer splint downword, and lay a sponge in
<li>Activation PVDF membrane in advance with anhydrous ethanol, and put it on the membrane.</li>
+
                        it. Several filter paper(three pieces of filter paper), glue(except Stacking Gel).
<li>Three layers of filter paper, sponge, Squeeze out of the bubbles, turn tight.</li>
+
                    </li>
<li>the black subface electric rotary groove stick to each other, put in ice.</li>
+
                    <li>Activation PVDF membrane in advance with anhydrous ethanol, and put it on the membrane.</li>
<li>110V,120min.</li>
+
                    <li>Three layers of filter paper, sponge, Squeeze out of the bubbles, turn tight.</li>
<li>5% skim milk powder (prepared by PBST), block for a night.</li>
+
                    <li>the black subface electric rotary groove stick to each other, put in ice.</li>
<li>Dilute Primary antibody at the proportion of 1:2000 with 3% skim milk powder(add 0.02% sodium azide ), incubate 1h at the room temperature.</li>
+
                    <li>110V,120min.</li>
<li>PBST elute, wash with shocking for 5min , three times.</li>
+
                    <li>5% skim milk powder (prepared by PBST), block for a night.</li>
<li>Dilute Secondary antibody at the proportion of 1:2000 with 3% skim milk powder, incubate 1h at the room temperature.</li>
+
                    <li>Dilute Primary antibody at the proportion of 1:2000 with 3% skim milk powder(add 0.02% sodium
<li>PBST elute, wash with shocking for 5min, three times.</li>
+
                        azide ), incubate 1h at the room temperature.
<li>Color development.</li>
+
                    </li>
</ol>
+
                    <li>PBST elute, wash with shocking for 5min , three times.</li>
 +
                    <li>Dilute Secondary antibody at the proportion of 1:2000 with 3% skim milk powder, incubate 1h at
 +
                        the room temperature.
 +
                    </li>
 +
                    <li>PBST elute, wash with shocking for 5min, three times.</li>
 +
                    <li>Color development.</li>
 +
                </ol>
  
<h2>Ni-beads protein purification</h2>
+
                <h2>Ni-beads protein purification</h2>
  
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="2"> NPI-10 buffer(1L)pH=8.0 filtration sterilization </th>
+
                        <th style="text-align: center" colspan="2"> NPI-10 buffer(1L)pH=8.0 filtration sterilization
</tr>
+
                        </th>
<tr>
+
                    </tr>
<td align="center">Reagent</td>
+
                    <tr>
<td align="center">NaH2PO4·H2O</td>
+
                        <td align="center">Reagent</td>
<td align="center">NaCl</td>
+
                        <td align="center">NaH2PO4·H2O</td>
<td align="center">imidazole</td>
+
                        <td align="center">NaCl</td>
</tr>
+
                        <td align="center">imidazole</td>
<tr>
+
                    </tr>
<td align="center">Dosage</td>
+
                    <tr>
<td align="center">6.9</td>
+
                        <td align="center">Dosage</td>
<td align="center">17.54</td>
+
                        <td align="center">6.9</td>
<td align="center">0.68</td>
+
                        <td align="center">17.54</td>
</tr>
+
                        <td align="center">0.68</td>
</table>
+
                    </tr>
 +
                </table>
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="2">NPI-20 buffer(1L)pH=8.0 filtration sterilization</th>
+
                        <th style="text-align: center" colspan="2">NPI-20 buffer(1L)pH=8.0 filtration sterilization</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">NaH2PO4·H2O</td>
+
                        <td align="center">NaH2PO4·H2O</td>
<td align="center">NaCl</td>
+
                        <td align="center">NaCl</td>
<td align="center">imidazole</td>
+
                        <td align="center">imidazole</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage (g)</td>
+
                        <td align="center">Dosage (g)</td>
<td align="center">6.9</td>
+
                        <td align="center">6.9</td>
<td align="center">17.54</td>
+
                        <td align="center">17.54</td>
<td align="center">1.36</td>
+
                        <td align="center">1.36</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="2">NPI-250 buffer(1L)pH=8.0 filtration sterilization</th>
+
                        <th style="text-align: center" colspan="2">NPI-250 buffer(1L)pH=8.0 filtration sterilization
</tr>
+
                        </th>
<tr>
+
                    </tr>
<td align="center">Reagent </td>
+
                    <tr>
<td align="center">NaH2PO4·H2O</td>
+
                        <td align="center">Reagent</td>
<td align="center">NaCl</td>
+
                        <td align="center">NaH2PO4·H2O</td>
<td align="center">imidazole </td>
+
                        <td align="center">NaCl</td>
</tr>
+
                        <td align="center">imidazole</td>
<tr>
+
                    </tr>
<td align="center">Dosage (g)</td>
+
                    <tr>
<td align="center">6.9</td>
+
                        <td align="center">Dosage (g)</td>
<td align="center">17.54</td>
+
                        <td align="center">6.9</td>
<td align="center">17.0</td>
+
                        <td align="center">17.54</td>
</tr>
+
                        <td align="center">17.0</td>
</table>
+
                    </tr>
 +
                </table>
  
<h4>Protocol</h4>
+
                <h4>Protocol</h4>
<ol>
+
                <ol>
<li>Cut tips. Add 30μL Ni 6 fast flow Beads into 1.5mL EP.</li>
+
                    <li>Cut tips. Add 30μL Ni 6 fast flow Beads into 1.5mL EP.</li>
<li>Add 1mL NPI-10 buffer, mixing wash, sedimentate at low speed and wash 3 times.</li>
+
                    <li>Add 1mL NPI-10 buffer, mixing wash, sedimentate at low speed and wash 3 times.</li>
<li>Centrifuge and absorb supernatant into buffer. 4℃ binding 3h,rotate and mix.</li>
+
                    <li>Centrifuge and absorb supernatant into buffer. 4℃ binding 3h,rotate and mix.</li>
<li>After binding, Put on ice(5min),Centrifuge at 2000rpm for 1min.</li>
+
                    <li>After binding, Put on ice(5min),Centrifuge at 2000rpm for 1min.</li>
<li>absorb 80μL supernatant as control and remove the other supernatant, add 1mL NPI-20 washing, upside and down to mix, still standing, Centrifuge at 2000rpm for 1min(4℃), wash 3~5 times.</li>
+
                    <li>absorb 80μL supernatant as control and remove the other supernatant, add 1mL NPI-20 washing,
<li>Add 500μL NPI-250 into Beads, rotate and mix for 15min, gather supernatant, add 500μL NPI-250 , rotate and mix for 15min, gather supernatant again.</li>
+
                        upside and down to mix, still standing, Centrifuge at 2000rpm for 1min(4℃), wash 3~5 times.
</ol>
+
                    </li>
 +
                    <li>Add 500μL NPI-250 into Beads, rotate and mix for 15min, gather supernatant, add 500μL NPI-250 ,
 +
                        rotate and mix for 15min, gather supernatant again.
 +
                    </li>
 +
                </ol>
  
<h2>Renaturation of the inclusion bodies</h2>
+
                <h2>Renaturation of the inclusion bodies</h2>
  
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="4">Binding buffer (1L) pH=8.0</th>
+
                        <th style="text-align: center" colspan="4">Binding buffer (1L) pH=8.0</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">NaCl(500mmol/L)</td>
+
                        <td align="center">NaCl(500mmol/L)</td>
<td align="center">Na3PO4·12H2O(20mmol/L)</td>
+
                        <td align="center">Na3PO4·12H2O(20mmol/L)</td>
<td align="center">imidazole (20mmol/L)</td>
+
                        <td align="center">imidazole (20mmol/L)</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage(g)</td>
+
                        <td align="center">Dosage(g)</td>
<td align="center">29.22</td>
+
                        <td align="center">29.22</td>
<td align="center">7.6</td>
+
                        <td align="center">7.6</td>
<td align="center">1.36</td>
+
                        <td align="center">1.36</td>
</tr>
+
                    </tr>
</table>
+
                </table>
<p>After cell disruption, sediment dissolves in binding buffer(8mol/L urea)</p>
+
                <p>After cell disruption, sediment dissolves in binding buffer(8mol/L urea)</p>
<table class="table">
+
                <table class="table">
<tr>
+
                    <tr>
<th style="text-align: center" colspan="5">Washing buffer(1L) </th>
+
                        <th style="text-align: center" colspan="5">Washing buffer(1L)</th>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Reagent</td>
+
                        <td align="center">Reagent</td>
<td align="center">Tris-HCl(50mmol/L)</td>
+
                        <td align="center">Tris-HCl(50mmol/L)</td>
<td align="center">EDTA(5mmol/L)</td>
+
                        <td align="center">EDTA(5mmol/L)</td>
<td align="center">NaCl(100mmol/L)</td>
+
                        <td align="center">NaCl(100mmol/L)</td>
<td align="center">Triton X-100(1%)</td>
+
                        <td align="center">Triton X-100(1%)</td>
</tr>
+
                    </tr>
<tr>
+
                    <tr>
<td align="center">Dosage</td>
+
                        <td align="center">Dosage</td>
<td align="center">100mL</td>
+
                        <td align="center">100mL</td>
<td align="center">1.8612g</td>
+
                        <td align="center">1.8612g</td>
<td align="center">5.844g</td>
+
                        <td align="center">5.844g</td>
<td align="center">10mL</td>
+
                        <td align="center">10mL</td>
</tr>
+
                    </tr>
</table>
+
                </table>
  
<ol>
+
                <ol>
<li>Induced expression</li>
+
                    <li>Induced expression</li>
<li>Collect sediment after ultrasonication, use washing buffer including 2,3mol/L urea to wash sediment in turn. Finally, use washing buffer including 8mol/L urea to dissolve. Centrifuge and absorb supernatant, measure protein concentration and make it keep about 1mg/mL. Dialyze these supernatant using binding buffer including concentration gradient urea(6,5,4,3,2,1,0.5 and 0mol/L).</li>
+
                    <li>Collect sediment after ultrasonication, use washing buffer including 2,3mol/L urea to wash
</ol>
+
                        sediment in turn. Finally, use washing buffer including 8mol/L urea to dissolve. Centrifuge and
 +
                        absorb supernatant, measure protein concentration and make it keep about 1mg/mL. Dialyze these
 +
                        supernatant using binding buffer including concentration gradient urea(6,5,4,3,2,1,0.5 and
 +
                        0mol/L).
 +
                    </li>
 +
                </ol>
  
  
<h2>Extraction tubulin from porcine brains</h2>
+
                <h2>Extraction tubulin from porcine brains</h2>
<ol>
+
                <ol>
<li>Picked up 20 porcine brains from Beijing No.5 Meat Processing. For tubulin extraction experiment, the brains should be as fresh as possible. Take an ice box to store the brains. Avoid contact between the brains.</li>
+
                    <li>Picked up 20 porcine brains from Beijing No.5 Meat Processing. For tubulin extraction
<li>While getting the brains, another student should stay in the lab and prepared the centrifuge (set one at 4℃ and another at 37℃, also pre-warm the rotor). Put electronic balance, grinder, a graduated cylinder in refrigerator and pre-warm the glycerol and PEM in 37℃. prepare the fresh ATP and GTP buffer in the morning.</li>
+
                        experiment, the brains should be as fresh as possible. Take an ice box to store the brains.
<li>Clean the brain by tearing off the meninges and blood clots using kim wipes or by hand. </li>
+
                        Avoid contact between the brains.
<li>After cleaning, weigh the brains, put the brains in the blender, then add the same volume buffer PEM(with 1 mM DTT) in it accordingly.</li>
+
                    </li>
<li>Homogenate the brain for 3 s, 10 times, time interval between two homogenate is 5 s, in order to avoid destroy the tubulin because of high thermos.</li>
+
                    <li>While getting the brains, another student should stay in the lab and prepared the centrifuge
<li>Pour the homogenate into a flask, incubate in 4℃ for 30 min to depolymerize microtubules. </li>
+
                        (set one at 4℃ and another at 37℃, also pre-warm the rotor). Put electronic balance, grinder, a
<li>Pour the homogenate into tubes for Type 45Ti rotor and balance each tube. </li>
+
                        graduated cylinder in refrigerator and pre-warm the glycerol and PEM in 37℃. prepare the fresh
<li>Centrifuge at 8000 rpm for 40 min at 4 ℃. Filter the supernatant with 4 gauzes. Then centrifuge the filtrate at 40000 g for 40 min at 4℃.</li>
+
                        ATP and GTP buffer in the morning.
<li>Add 1/2 volume of warmed glycerol drop-wise with continuous shaking, mix gently but thoroughly. Add GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 3 mmol/L), and EGTA (final concentration 1 mmol/L). Incubate in a 37℃ water bath for 1 h, shake gently and occasionally.</li>
+
                    </li>
<li>Balance each tube and centrifuge at 100000 g for 40 min at 35℃.Discard supernatant, the pellet is crude extracts. Split charge them into 50 ml centrifuge tubes, each tube contains 5 g. Snap freeze the tubulin in 15 ul aliquots in liquid nitrogen and further stored at -80 ℃.</li>
+
                    <li>Clean the brain by tearing off the meninges and blood clots using kim wipes or by hand.</li>
<li>When going to do refined depuration, melt the freezing crude extract at 4 ℃ refrigerator on ice over night. Pop out 1 g of the pellet out of the tubes with a spatula. Put the pellets in the Dounce grinder, then add cold PEM in the tube to wash off residual pellets. </li>
+
                    <li>After cleaning, weigh the brains, put the brains in the blender, then add the same volume buffer
<li>Re-suspend the pellets with grinder, keep the grinder on ice, and grinding occasionally. After 30 min, pour out the solution and rinse the grinder with cold PEM. Total re-suspended volume is 5 ml.</li>
+
                        PEM(with 1 mM DTT) in it accordingly.
<li>Add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.</li>
+
                    </li>
<li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.</li>
+
                    <li>Homogenate the brain for 3 s, 10 times, time interval between two homogenate is 5 s, in order to
<li>Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES( pH =6.9 ), DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.</li>
+
                        avoid destroy the tubulin because of high thermos.
<li>Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.</li>
+
                    </li>
<li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃. </li>
+
                    <li>Pour the homogenate into a flask, incubate in 4℃ for 30 min to depolymerize microtubules.</li>
<li>Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.</li>
+
                    <li>Pour the homogenate into tubes for Type 45Ti rotor and balance each tube.</li>
<li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.</li>
+
                    <li>Centrifuge at 8000 rpm for 40 min at 4 ℃. Filter the supernatant with 4 gauzes. Then centrifuge
<li>Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES ( pH= 6.9 ), DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.</li>
+
                        the filtrate at 40000 g for 40 min at 4℃.
<li>Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.</li>
+
                    </li>
<li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃. </li>
+
                    <li>Add 1/2 volume of warmed glycerol drop-wise with continuous shaking, mix gently but thoroughly.
<li>Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.</li>
+
                        Add GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 3 mmol/L), and EGTA (final
<li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4℃.</li>
+
                        concentration 1 mmol/L). Incubate in a 37℃ water bath for 1 h, shake gently and occasionally.
<li>Recover the supernatant, add equal volume polymerize buffer (containing 100 mmol/L PIPES-KOH, 2 mmol/L EGTA, 2 mmol/L MgCl2, 2 mmol/L GTP and 60% glycerol).</li>
+
                    </li>
<li>Incubate in a 37℃ water bath for 1 h. </li>
+
                    <li>Balance each tube and centrifuge at 100000 g for 40 min at 35℃.Discard supernatant, the pellet
<li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃. The pellet is fine purified product.</li>
+
                        is crude extracts. Split charge them into 50 ml centrifuge tubes, each tube contains 5 g. Snap
</ol>
+
                        freeze the tubulin in 15 ul aliquots in liquid nitrogen and further stored at -80 ℃.
 +
                    </li>
 +
                    <li>When going to do refined depuration, melt the freezing crude extract at 4 ℃ refrigerator on ice
 +
                        over night. Pop out 1 g of the pellet out of the tubes with a spatula. Put the pellets in the
 +
                        Dounce grinder, then add cold PEM in the tube to wash off residual pellets.
 +
                    </li>
 +
                    <li>Re-suspend the pellets with grinder, keep the grinder on ice, and grinding occasionally. After
 +
                        30 min, pour out the solution and rinse the grinder with cold PEM. Total re-suspended volume is
 +
                        5 ml.
 +
                    </li>
 +
                    <li>Add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it
 +
                        occasionally.
 +
                    </li>
 +
                    <li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.</li>
 +
                    <li>Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES( pH =6.9 ),
 +
                        DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration
 +
                        1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.
 +
                    </li>
 +
                    <li>Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.</li>
 +
                    <li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃.</li>
 +
                    <li>Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration
 +
                        0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.
 +
                    </li>
 +
                    <li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.</li>
 +
                    <li>Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES ( pH= 6.9 ),
 +
                        DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration
 +
                        1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.
 +
                    </li>
 +
                    <li>Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.</li>
 +
                    <li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃.</li>
 +
                    <li>Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration
 +
                        0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.
 +
                    </li>
 +
                    <li>Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4℃.</li>
 +
                    <li>Recover the supernatant, add equal volume polymerize buffer (containing 100 mmol/L PIPES-KOH, 2
 +
                        mmol/L EGTA, 2 mmol/L MgCl2, 2 mmol/L GTP and 60% glycerol).
 +
                    </li>
 +
                    <li>Incubate in a 37℃ water bath for 1 h.</li>
 +
                    <li>Balance each tube and centrifuge at 100000 g for 1 h at 35℃. The pellet is fine purified
 +
                        product.
 +
                    </li>
 +
                </ol>
  
  
<h2>Improvement</h2>
+
                <h2>Improvement</h2>
<h3>Culture and collection</h3>
+
                <h3>Culture and collection</h3>
<ol>
+
                <ol>
<li>Use LB medium to preculture transformed media 5 ml for 12 hrs, 200 rpm/ 37℃.</li>
+
                    <li>Use LB medium to preculture transformed media 5 ml for 12 hrs, 200 rpm/ 37℃.</li>
<li>Culture 5 mL preculture media into 100 mL TB medium for about 3 hrs until OD=0.4~0.6, 200 rpm/ 37℃.</li>
+
                    <li>Culture 5 mL preculture media into 100 mL TB medium for about 3 hrs until OD=0.4~0.6, 200 rpm/
<li>Add arabinose or turn to 42℃ to induce P(3HB) expression for 72 hrs, 220rpm.</li>
+
                        37℃.
<li>Collect cells and centrifuge for 3 min, 5,000 rpm.</li>
+
                    </li>
<li>Remove supernatant and suspend with pure water.</li>
+
                    <li>Add arabinose or turn to 42℃ to induce P(3HB) expression for 72 hrs, 220rpm.</li>
<li>Centrifuge again for 3 min, 5,000 rpm and remove its supernatant.</li>
+
                    <li>Collect cells and centrifuge for 3 min, 5,000 rpm.</li>
</ol>
+
                    <li>Remove supernatant and suspend with pure water.</li>
 +
                    <li>Centrifuge again for 3 min, 5,000 rpm and remove its supernatant.</li>
 +
                </ol>
  
  
<h3>Extract PHB<sup>1</sup></h3>
+
                <h3>Extract PHB<sup>1</sup></h3>
<ul>
+
                <ul>
<li>Centrifuge settings: 4000RPM, 10mins.</li>
+
                    <li>Centrifuge settings: 4000RPM, 10mins.</li>
<li> Scale as appropriate.</li>
+
                    <li> Scale as appropriate.</li>
<li> After each centrifuge step the supernatant should be poured off.</li>
+
                    <li> After each centrifuge step the supernatant should be poured off.</li>
</ul>
+
                </ul>
<ol>
+
                <ol>
<li>Resuspend precipitation in 10 mL Triton X-100(1% v/v in PBS) for 30mins at room temp.</li>
+
                    <li>Resuspend precipitation in 10 mL Triton X-100(1% v/v in PBS) for 30mins at room temp.</li>
<li>Centrifuge, resuspend in 10 mL PBS.</li>
+
                    <li>Centrifuge, resuspend in 10 mL PBS.</li>
<li>Centrifuge, add 10 mL sodium hyperchlorite solution and incubate at 30˚C for 1 hour.</li>
+
                    <li>Centrifuge, add 10 mL sodium hyperchlorite solution and incubate at 30˚C for 1 hour.</li>
<li>Centrifuge, wash with 10 mL 70% EtOH.</li>
+
                    <li>Centrifuge, wash with 10 mL 70% EtOH.</li>
<li>Allow powder to dry.</li>
+
                    <li>Allow powder to dry.</li>
</ol>
+
                </ol>
<p>[1]: Shahryar Shakeri, Comparison of intracellular polyhydroxybutyrate granules formation between different bacterial cell subpopulations by flow cytometry, Jundishapur Journal of Microbiology 2011.</p>
+
                <p style="color: #5c5c5c;font-size: 13px;">[1]: Shahryar Shakeri, Comparison of intracellular
 +
                    polyhydroxybutyrate granules formation between different bacterial cell subpopulations by flow
 +
                    cytometry, Jundishapur Journal of Microbiology 2011.</p>
  
  
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Revision as of 18:24, 14 October 2016

Team:BNU-CHINA - 2016.igem.org

PROTOCOL

Cloning

PCR

Reaction system:


1.

\(H_2 O\ \ 2\mu L\)

\(10\mathrm{x}\ \ Taq \ \ buffer \ \ 5\mu\mathrm{L}\)

\(2.5mM \ \ dNTP \ \ 1\mu\mathrm{L}\)

\(R+F-Primer \ \ 10\mu\mathrm{L}\)

\(Template \ \ 10\mu\mathrm{L}\)

\(Taq \ \ 2.5\mu\mathrm{L}\)

\(Universal \ \ DNA \ \ polymerase \ \ TransGen\)


2.

\(H_2 O\ \ 20\mu\mathrm{L}\)

\(5\mathrm{x}\ \ Taq\ \ buffer\ \ 10\mu\mathrm{L}\)

\(2.5mM\ \ dNTP\ \ 5\mu\mathrm{L}\)

\(R+F-Primer\ \ 44\mu\mathrm{L}\)

\(Template\ \ 10\mu\mathrm{L}\)

\(Taq\ \ 1\mu\mathrm{L}\)


3.

\(primeSTAR\ \ from\ \ Takara\)

\(H_2 O\ \ 21\mu\mathrm{L}\)

\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)

\(R+F-Primer\ \ 2\mu\mathrm{L}\)

\(Template\ \ 2\mu\mathrm{L}\)

Process:

98°C 2min

\( \begin{equation} \left. \begin{array}{lcl} {98°C\ 10s} \\ {56°C\ 15s} \\{72°C\ 30s} \end{array} \right \} Cycle\ 35 \end{equation} \)

72°C 5min

4°C ---

98°C 2min

\(\begin{equation}\left. \begin{array}{lcl} {98°C\ 10s} \\ {55°C\ 5s} \\{72°C\ 8s} \end{array} \right\}Cycle\ 35\end{equation}\)

72°C 5min

15°C ---

Fusion PCR:
  1. basic PCR
  2. using the PCR product of step 1 as template does PCR
  3. using the PCR product of step 2 as template does PCR,but first five cycles don’t add primer, after first five cycles, the sixth cycle adds primer and continue PCR.
The system of step 2:

\(H_2 O\ \ 21\mu\mathrm{L}\)

\(2\mathrm{x}\ \ primeSTAR\ \ 25m\mathrm{L}\)

\(R+F-Primer\ \ 2\mu\mathrm{L}\)

\(Template①\ \ 1\mu\mathrm{L}\)

\(Template②\ \ 1\mu\mathrm{L}\)

Electrophoresis---Gel Purification

Material:

Agarose gel: 1% agarose dissolved in 1 x TAE + gelstain

Protocol:

We used gelstain to stain the DNA and imaged it in a Transilluminator.

We used the gel extraction kit to get the objective fragment.

We used the DNA fragment purification kit to get the objective fragment.

Digestion

\(50\mu\mathrm{L} \ \ \mathrm{reaction \ \ system}\)
Reagent 10x \(\ \mathrm{H \ buffer}\) \(Eco\mathrm{R}\ \mathrm{I}\) \(Pat\ \mathrm{I}\) \(\mathrm{Plasmid}\) \(\mathrm{H_2 O}\)
Dosage \(5\mu\mathrm{L}\) \(1.5\mu\mathrm{L}\) \(1.5\mu\mathrm{L}\) \(15\mu\mathrm{L}\) \(27\mu\mathrm{L}\)
\(10\mu\mathrm{L} \ \ \mathrm{reaction \ \ system}\)
Reagent 10x \(\ \mathrm{H \ buffer}\) \(Eco\mathrm{R}\ \mathrm{I}\) \(Pat\ \mathrm{I}\) \(\mathrm{Plasmid}\) \(\mathrm{H_2 O}\)
Dosage \(1\mu\mathrm{L}\) \(0.3\mu\mathrm{L}\) \(0.3\mu\mathrm{L}\) \(3\mu\mathrm{L}\) \(5.4\mu\mathrm{L}\)

Ligation

Ligation reaction system
Reagent DNA Plasmid T4 buffer T4 ligase
Dosage \(7\mu\mathrm{L}\) \(1\mu\mathrm{L}\) \(1\mu\mathrm{L}\) \(1\mu\mathrm{L}\)

LR reaction

1. Entry linearization

β2-TOPO(plasmid concentration 117ng/μL) NotI 37°C enzyme digestion for the night

50μL Single enzyme system
10x BufferH 5μL
DNA 20μL
ddH2O 12.5μL
Enzyme 2.5μL
0.1%BSA 5μL
0.1%Triton X-100 5μL

2. LR system (\(4\mu\mathrm{L}\)):

100 ng/ul linear Entry: 0.5 ul

destination vector: 1 ul (pCambia1300-nluc / pCambia1300-cluceach one)

LR Clonase II enzyme mix: 1 ul

ddH2O: 0.5 ul

mix slightly,water base for 5 h at 25°C 

transform, 4 ul, reactant transform 50 ul competent cells

Transformation

Material:

LB liquid medium
Reagent Tryptone Yeast extract powder NaCl
Dosage 10 g/L 5 g/L 10 μL

Protocol:

preparation of the competent cells

1μL ligation product + 50μL cells

Heatshock of Trans5α(42°C,45s)

Put on ice(2min)

Add 500μL LB media and incubate for 1h(37°C, 150rpm)

Centrifuge at 4000rpm for 1min and remove 400μL supernatant

Resuspend the pellets using the left supernatant

Spread plates(with Kan;CHL)

Incubate for 12~16h(37°C)

Protein Expression

  1. Inoculated 3 mL LB media including relevant antibiotics with the monoclonal colony of expression plasmid, incubate for 12~16h(37°C, 190rpm)
  2. Inoculated 100 mL TM expression media including relevant antibiotics with the 1mL bacteria liquid, incubate for 3h(37°C, 250rpm,OD600=0.6~0.8)
  3. Add IPTG into it until its final concentration is 1mmol/L, incubate for 4~6h(37°C, 250rpm)
  4. Centrifuge at 6000rpm for 10min and remove supernatant
  5. Gather sediment, cryopreserve at -20°C

Material:

TM expression medium:1000mL PH=7.4

Reagent tryptone Yeast extract powder NaCl glucose glycerol
Dosage 1.2g 2.4g 1.0g 1.0g 0.6mL

Autoclaving 115℃,20min

Detetion

SDS-PAGE

Materials

Gel Tris-HCl Acr/Bis 30% SDS 10% ddH2O TEMED AP 10%
Stacking Gel(4%) pH=6.8 500μL 500 μL 25 μL 1350μL 2.5μL 12.5μL
Running Gel(12%) pH=8.8 1250μL 2000 μL 50 μL 1675μL 2.5μL 25 μL
Running Gel(18%) pH=8.8 1250μL 3000 μL 50 μL 675 μL 2.5μL 25 μL
Running Buffer
Reagent Tris-HCl Glycine (w/v) SDS
Dosage 25 mmol/L 0.192 mol/L 0.1%

Protocol

The SDS polyacrylamide gels are prepared in the so-called PerfectBlue™ Twin Double Gel System.

After ensuring that the equipment is waterproof, the 12 % (or 18%) running gel is mixed and filled into the chamber. Pipetting about 1 ml of H2O on top of the running gel to seal the gel.

After polymerization, the remaining H2O is removed and the 12 % stacking gel is filled on top. Insert a comb to create sample pockets.

After the stacking gel also polymerized, 1 x running buffer is used to run the Double Gel System via the SDS gel.

After loading the generated pockets with the samples, the stacking gel is run at 100 V and then running gel at 120 V.

Western Blot

System

PBST:1000mL(PH=7.4)
Reagent NaCl(137mM) KCl(2.7mM) Na2HPO4(10mM) K2HPO4(2mM) Tween-20
Dosage 8g 0.2g 1.44g 0.24g 0.5mL
Imprint buffer:2000mL (PH=8.3) Transfer Buffer
Reagent Tris Gly Methanol
Dosage 6.06g 28.8g 400mL

Protocol

Transfer (Prepare transfer Buffer just before glue leaking, and precool at -20℃).

  1. Put the transfer Buffer and the black subface of transfer splint downword, and lay a sponge in it. Several filter paper(three pieces of filter paper), glue(except Stacking Gel).
  2. Activation PVDF membrane in advance with anhydrous ethanol, and put it on the membrane.
  3. Three layers of filter paper, sponge, Squeeze out of the bubbles, turn tight.
  4. the black subface electric rotary groove stick to each other, put in ice.
  5. 110V,120min.
  6. 5% skim milk powder (prepared by PBST), block for a night.
  7. Dilute Primary antibody at the proportion of 1:2000 with 3% skim milk powder(add 0.02% sodium azide ), incubate 1h at the room temperature.
  8. PBST elute, wash with shocking for 5min , three times.
  9. Dilute Secondary antibody at the proportion of 1:2000 with 3% skim milk powder, incubate 1h at the room temperature.
  10. PBST elute, wash with shocking for 5min, three times.
  11. Color development.

Ni-beads protein purification

NPI-10 buffer(1L)pH=8.0 filtration sterilization
Reagent NaH2PO4·H2O NaCl imidazole
Dosage 6.9 17.54 0.68
NPI-20 buffer(1L)pH=8.0 filtration sterilization
Reagent NaH2PO4·H2O NaCl imidazole
Dosage (g) 6.9 17.54 1.36
NPI-250 buffer(1L)pH=8.0 filtration sterilization
Reagent NaH2PO4·H2O NaCl imidazole
Dosage (g) 6.9 17.54 17.0

Protocol

  1. Cut tips. Add 30μL Ni 6 fast flow Beads into 1.5mL EP.
  2. Add 1mL NPI-10 buffer, mixing wash, sedimentate at low speed and wash 3 times.
  3. Centrifuge and absorb supernatant into buffer. 4℃ binding 3h,rotate and mix.
  4. After binding, Put on ice(5min),Centrifuge at 2000rpm for 1min.
  5. absorb 80μL supernatant as control and remove the other supernatant, add 1mL NPI-20 washing, upside and down to mix, still standing, Centrifuge at 2000rpm for 1min(4℃), wash 3~5 times.
  6. Add 500μL NPI-250 into Beads, rotate and mix for 15min, gather supernatant, add 500μL NPI-250 , rotate and mix for 15min, gather supernatant again.

Renaturation of the inclusion bodies

Binding buffer (1L) pH=8.0
Reagent NaCl(500mmol/L) Na3PO4·12H2O(20mmol/L) imidazole (20mmol/L)
Dosage(g) 29.22 7.6 1.36

After cell disruption, sediment dissolves in binding buffer(8mol/L urea)

Washing buffer(1L)
Reagent Tris-HCl(50mmol/L) EDTA(5mmol/L) NaCl(100mmol/L) Triton X-100(1%)
Dosage 100mL 1.8612g 5.844g 10mL
  1. Induced expression
  2. Collect sediment after ultrasonication, use washing buffer including 2,3mol/L urea to wash sediment in turn. Finally, use washing buffer including 8mol/L urea to dissolve. Centrifuge and absorb supernatant, measure protein concentration and make it keep about 1mg/mL. Dialyze these supernatant using binding buffer including concentration gradient urea(6,5,4,3,2,1,0.5 and 0mol/L).

Extraction tubulin from porcine brains

  1. Picked up 20 porcine brains from Beijing No.5 Meat Processing. For tubulin extraction experiment, the brains should be as fresh as possible. Take an ice box to store the brains. Avoid contact between the brains.
  2. While getting the brains, another student should stay in the lab and prepared the centrifuge (set one at 4℃ and another at 37℃, also pre-warm the rotor). Put electronic balance, grinder, a graduated cylinder in refrigerator and pre-warm the glycerol and PEM in 37℃. prepare the fresh ATP and GTP buffer in the morning.
  3. Clean the brain by tearing off the meninges and blood clots using kim wipes or by hand.
  4. After cleaning, weigh the brains, put the brains in the blender, then add the same volume buffer PEM(with 1 mM DTT) in it accordingly.
  5. Homogenate the brain for 3 s, 10 times, time interval between two homogenate is 5 s, in order to avoid destroy the tubulin because of high thermos.
  6. Pour the homogenate into a flask, incubate in 4℃ for 30 min to depolymerize microtubules.
  7. Pour the homogenate into tubes for Type 45Ti rotor and balance each tube.
  8. Centrifuge at 8000 rpm for 40 min at 4 ℃. Filter the supernatant with 4 gauzes. Then centrifuge the filtrate at 40000 g for 40 min at 4℃.
  9. Add 1/2 volume of warmed glycerol drop-wise with continuous shaking, mix gently but thoroughly. Add GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 3 mmol/L), and EGTA (final concentration 1 mmol/L). Incubate in a 37℃ water bath for 1 h, shake gently and occasionally.
  10. Balance each tube and centrifuge at 100000 g for 40 min at 35℃.Discard supernatant, the pellet is crude extracts. Split charge them into 50 ml centrifuge tubes, each tube contains 5 g. Snap freeze the tubulin in 15 ul aliquots in liquid nitrogen and further stored at -80 ℃.
  11. When going to do refined depuration, melt the freezing crude extract at 4 ℃ refrigerator on ice over night. Pop out 1 g of the pellet out of the tubes with a spatula. Put the pellets in the Dounce grinder, then add cold PEM in the tube to wash off residual pellets.
  12. Re-suspend the pellets with grinder, keep the grinder on ice, and grinding occasionally. After 30 min, pour out the solution and rinse the grinder with cold PEM. Total re-suspended volume is 5 ml.
  13. Add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.
  14. Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.
  15. Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES( pH =6.9 ), DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.
  16. Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.
  17. Balance each tube and centrifuge at 100000 g for 1 h at 35℃.
  18. Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.
  19. Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4 ℃.
  20. Recover the supernatant and pour it into a flask. Add equal volume of warmed PIPES ( pH= 6.9 ), DMSO(final concentration 10%), GTP (final concentration 0.1 mmol/L), MgCl2 (final concentration 1 mmol/L) and EGTA (final concentration 1 mmol/L). Mix gently but thoroughly.
  21. Incubate in a 37℃ water bath for 1 h. the solution would look cloudy.
  22. Balance each tube and centrifuge at 100000 g for 1 h at 35℃.
  23. Discard the supernatant. Risen the pellet briefly with cold PEM, add GTP (final concentration 0.1 mmol/L). Place it on ice for 1 h to depolymerize. Shake it occasionally.
  24. Centrifuge the depolymerized tubulin at 100000 g for 40 min at 4℃.
  25. Recover the supernatant, add equal volume polymerize buffer (containing 100 mmol/L PIPES-KOH, 2 mmol/L EGTA, 2 mmol/L MgCl2, 2 mmol/L GTP and 60% glycerol).
  26. Incubate in a 37℃ water bath for 1 h.
  27. Balance each tube and centrifuge at 100000 g for 1 h at 35℃. The pellet is fine purified product.

Improvement

Culture and collection

  1. Use LB medium to preculture transformed media 5 ml for 12 hrs, 200 rpm/ 37℃.
  2. Culture 5 mL preculture media into 100 mL TB medium for about 3 hrs until OD=0.4~0.6, 200 rpm/ 37℃.
  3. Add arabinose or turn to 42℃ to induce P(3HB) expression for 72 hrs, 220rpm.
  4. Collect cells and centrifuge for 3 min, 5,000 rpm.
  5. Remove supernatant and suspend with pure water.
  6. Centrifuge again for 3 min, 5,000 rpm and remove its supernatant.

Extract PHB1

  • Centrifuge settings: 4000RPM, 10mins.
  • Scale as appropriate.
  • After each centrifuge step the supernatant should be poured off.
  1. Resuspend precipitation in 10 mL Triton X-100(1% v/v in PBS) for 30mins at room temp.
  2. Centrifuge, resuspend in 10 mL PBS.
  3. Centrifuge, add 10 mL sodium hyperchlorite solution and incubate at 30˚C for 1 hour.
  4. Centrifuge, wash with 10 mL 70% EtOH.
  5. Allow powder to dry.

[1]: Shahryar Shakeri, Comparison of intracellular polyhydroxybutyrate granules formation between different bacterial cell subpopulations by flow cytometry, Jundishapur Journal of Microbiology 2011.