<a href="#exp1"><h4> 47.Digestion of pET43.1 (a) with Xba I and Hind III </h4></a></br>  

         <a href="#exp4"><h4> 50. Electrophoresis on agarose gel of pET43.1a(+) digest by Xba I and Hind III</h4></a></br>  

         <a href="#exp5"><h4> 51. Extraction of gel of pET43.1a(+) digested by Xba I and Hind III</h4></a></br>  

         <a href="#exp6"><h4> 52. Dephosphorylation of pET43.1a(+) (digest by Xba I/Hind III) done previously</h4></a></br>  

         <a href="#exp7"><h4> 53. Dephosphorylation of pET43.1a(+)digest by Xba I/Hind III) </h4></a></br>  

         <a href="#exp9"><h4> 55. Ligation of pET43.1a(+) dephosphorylated with C2</h4></a></br>  

         <a href="#exp10"><h4> 56. Electrophoresis on agarose gel of pET43.1 digest by Xba I and Hind III</h4></a></br>  

         <a href="#exp11"><h4> 57. Electrophoresis of pET43.1a(+) digested by Xba I and Hind III </h4></a></br>  

         <a href="#exp12"><h4> 58. Plasmid concentration measurement </h4></a></br>  

         <a href="#exp13"><h4> 59. Transformation of DH5&alpha; competent cells </h4></a></br>  

       <a href="#exp14"><h4> 60. Verification of transformation of the 5 July 2016</h4></a></br>   

           <a href="#exp19"><h4> 65. Check of transformation done on the July 6, 2016 </h4></a></br>  

           <a href="#exp20"><h4> 66. Extraction of DNA from colonies from 06 July 2016 </h4></a></br>  

           <a href="#exp21"><h4> 67. Agarose gel electrophoresis</h4></a></br>  

           <a href="#exp24"><h4> 70. Electrophoresis of pET43.1a(+) </h4></a></br>  

           <a href="#exp25"><h4> 71. Digestion of the recombinant plasmid </h4></a></br>  

           <a href="#exp26"><h4> 72. Electrophoresis of our results</h4></a></br>  

                 <U> Aim:</U>We repeated the previous experiment to understand why transformation in our bacteria didn't not work.</br></br>

                 • pET43.1a(+)a plasmid (obtained with Midiprep done on June 8, 2016)</br>

                 • enzyme restriction (Xba I / Hind III)</br>

                 • H₂O</br>

                 • P10 pipet, P20 pipet, 1.5 ml Eppendorf, 37°C and 65°C water bath</br></br>

                     1.  For our manipulation, we used Xba I and Hind III enzymes and we used Cutsmart 10X buffer because it is the most appropriate buffer.</br>

                           <th>pET43.1a(+) à 130 ng/&#181;l (3 &#181;g)</th>

                           <td><strong><p>DNA (&#181;l)</p></strong></td>

                           <td><strong>Xba I (&#181;l) </strong></td>

                           <td><strong>Hind III (&#181;l)</strong></td>

                           <td><strong>H₂0 (&#181;l)</strong></td>

                           <td><strong>CutSmart 10X (&#181;l)</strong></td>

                           <td><strong>TOTAL (&#181;l) </strong></td>

                       <th>pET43.1a(+)  Xba I/Hind III</th>

                       <td>260 ng/µl</td>

                       <td>400 ng/&#181;l</td>

                 • pET43.1a(+) plasmid digested by Xba I/Hind III</br>

                 • DNA ladder (Thermoscientific Gene ruler 1 kb)</br>

                 • P10 and P20 pipet, 1.5 Eppendorf, </br>electrophoresis BIORAD Mini-Sub Cell GT</br>

                       <th>Lane</th>

                       <td><strong>H₂0 (µl)</strong></td>

                 We saw that in the line of the plasmid cut by Xba I and Hind III, we have two bands which don’t correspond to the uncut plasmid band. Moreover, The band of the plasmid cut by Xba I and Hind III have the appropriate weight. So we can conclude that the digestion has worked. We can get back our plasmid cut with extraction gel.

                 • Dephosphorylation with rSAP enzyme</br>

                 • P10 and P200 pipet, 1.5 Eppendorf, water bath (37 °C and 65 °C)</br>

                 <U> Aim:</U>To save time, we do another dephosphorylation of pET43.1 digested by enzymes to ligate it to the insert C2 (digest by Xba I/Hind III on June,28 2016). </br></br>

                 • pET43.1a plasmid digested by Xba I/Hind III</br>

                 • P10 and P200 pipet, 1.5 Eppendorf, water bath (37 °C and 65 °C)</br>

                 <U> Aim:</U>We want to obtain a second expression vector, this time with pET43.1a(+) and C2. We do the same experiment as previously performed for C1.</br></br>

                 • pET43.1a(+) plasmid digested by Xba I/Hind III and dephosphorylated</br>

                 • C2 insert cut by Xba I/Hind III (done on the June,28 2016)</br>

                     <td><strong><p>H₂0 (µl)</p></strong></td>

                 • C2 insert cut by Xba I/Hind III (done on the june,28 2016)</br>

                 1.  For volums, refer to the next table :></br>></br>

                   C2 = 11.4 ng/µl></br>

                   pET43.1 = 50 ng/µl (900 ng  60 µl)></br>

                                         <td><strong><p>pET43.1a(+) (50 mg) (µl)</p></strong></td>

                                         <td><strong><p>H₂0 (µl) </p></strong></td>

                 • pET43.1a plasmid </br>

                 • pET43.1a plasmid cutted by Hind III/Xba I</br>

                 • C1 and C2 cutted by Hind III/Xba I</br>

                 • TAE 0.5X buffer</br>

                 • DNA ladder (Thermoscientific Gene ruler 1 kb)</br>

                       <td>pET43.1a(+) uncut</td>

                 • pET43.1a plasmid </br>

                 • pET43.1a plasmid cutted by Hind III/Xba I</br>

                 • C1 and C2 cut by Hind III/Xba I</br>

                 • TAE 0.5X buffer</br>

                 • P10 pipet, P20 pipet, test tube 250 ml, electrophoresis BIORAD Mini-Sub Cell GT, 2 type of tips, 1.5ml Eppendorf sterile tubes, 37°C water bath, shaking incubator centrifuge 5415D, </br></br>

                       <td>pET43.1a(+) uncut</td>     

               MpET43.1 = 5 300 bp * 660 g.mol^-1.bp^-1</br>

               MpET43.1 = 3.5*10-6 g.mol^-1</br>

               After condensation, we eliminate 5299 molecules of water (one between each bp), so we have 0.1*10⁶ g/mol</br></br>

               MpET43.1 = 3.4*106 g.mol^-1</br>

               Minsert = 5.6*105 g.mol^-1</br></br>

               - We have 0.12 µmol/l in 20 µl, and we must have 10 pg to have a good yield in colonies. </br>

               - Finally, we have 0.12 * 20*10^-6 = 2.4*10^-6 µmol of plasmid and 8.16 pg of plasmid. </br>

                 <U> Aim:</U>:  To make stock cells containing the plasmids, we need to enter the plasmid with C1 and C2 insert into the bacteria DH5&alpha; competent cells.</br></br>

                 <U>Materials:</U></br>competent cells, SOC media, 42°C waterbath, LB/carbenicillin 50 mg/ml.</br>

                 1- In five 1.5 ml eppendorf tubes, we put 40 µl of DH5&alpha; competent cells and we add 5 µl of : </br>

               Only two colonies have grown on the plate C2 (1:3), all the other petri dishes were empty. </br>

                 <U> Aim:</U>We want to increase the number of bacteria to check if they have the right plasmid. As we have two colonies, therefore we placed them to grow in liquid media in two 50 ml Falcons. </br></br>

                 <U> Aim:</U>The previous experiment being still underway, we want to move ahead with the other inserts. We want to digest our B2 insert to put it in the expression vector.</br></br>

                 • Eppendorf (0.5 ml)</br>

                 • Enzymes (Hind III and Xba I)</br>

                 • H₂O RNAse free</br>

                         <td><strong>A_{Vol Xba I}</strong></td>

                 <U> Aim:</U>Then we do the ligation of the insert B2 with pET43.1 and the transformation of all our products of ligation B2/C1 mix and empty plasmid as control. </br></br>

                 &bull;B2 (1 : 1)    Nothing has grown</br>

                 &bull;B2 (1 : 3)    Nothing has grown</br>

                 &bull;C2 (1 : 0)    Nothing has grown</br>

                 &bull;C1 mix        Nothing has grown</br>

                 &bull;C2 (1 :3) 1.1</br>

                 &bull;C2 (1 :3) 1.2</br>

                 &bull;C2 (1 :3) 2.1 </br>

                 &bull;C2 (1 :3) 2.2</br></br>

                 <U> Aim:</U>We want to check if our bacteria have produced enough ligated plasmid. </br></br>

                 Blank on TE 1X </br>

                       <td><strong><p>Xba I</p></strong></td>

                       <td><strong><p>Hind III</p></strong></td>

                       <td><strong><p>H₂0</p></strong></td>

                 1.  Add all reagents in a 1.5 ml Eppendorf </br>

                       <td>Marker weight</td>

                   After the elctrophoresis, we notice that the recombinant plasmid seems to contain two inserts. Indeed, the band corresponds to a size between 1 00 and 1 500 bp.</br>

                   We decided to digest our double insert with Xba I and Spe I to split it. </br>

                   We also digested a pET43.1 with Xba I and Spe I to prepare it for ligation. </br>

                 <U> Aim:</U>We observed that two inserts were present in our gels, we therefore want to verify that the second heavier one is not as a result of illegitimate ligation of Xba I/Hind III. There is a Spe I site in the neighboring sequences. Therefore, we want to split the insert to have just one insert.</br></br>

                       <td><strong><p>Vol Spe I (µl)</p></strong></td>

                       <td><strong><p>Vol Xba I (µl)</p></strong></td>

                     <td><strong><p>H₂0 10X (µl)</p></strong></td>

                 1.  To know the deposited volumes, refer to this table :</br>

                       <td>Marker weight</td>

                       <td><strong><p>H₂0 (µl)</p></strong></td>

                       <td><strong><p>H₂0 (µl)</p></strong></td>

                 <U>Results:</U>The digestion didn't work, we did not succeed in splitting the twinned insert so we decided to keep it and to express the protein with the double insert, hoping that the stop codon at the end of one of the inserts will be ennough. We will also sequence the plasmid to verify the orientation, and validity of our twinned insert hypothesis.</br></br>

                 <U> Aim:</U>In this part we wanted to proceed with the expression of our fusion protein containing the Si4-CBD-BPA. To do this we need a cell line having a T7 RNA polymerase. The cells we chose were BL21De3 pLys S. These contain the T7 phage producing the T7 RNA polymerase, and lysozyme, which will inhibit the T7 RNA polymrase and help control the expression better in case our protein is toxic to the cells, and secondly in case the cells escape our control they will not be able to survive in nature, as they will lyse over time.</br></br>

                   After heat shock at 42°C, and ice chill, the cells were allowed to recover by growing at 37°C for 40 minutes in 150 µl of SOC, then 200 µl of each sample were spread on a petri dish with carbenicillin 50 µg/ml and grown at 37 °C for one night.</br></br>