<p>A new plan was made to obtain the flagellums multi-functionality using affinity tags. We want to integrate a Strep-Tag into the flagellin so that the DARPin domain can be fused to the flagellum via streptavidin. </p>

     <p>Experiments  from Florian Altegoer have shown that mutants with D23-domain from <em>Salmonella</em> integrated into Hag are  expressing the modified flagellin and are motile. So the Strep-Tag was designed  into Hag with D2 as a linker domain with additional GSGS linkers.</p>

     <p>Additionally  the DARPin was designed with an N-terminal His-Tag and C-Terminal Streptavidin.</p>

     <p>The designed  structures were synthesized by Intefrated DNA Technologies.</p>

     <p>Based on the experiments from Florian Altegoer we decided to design Hag-D2-Cup.</p>

     <p>The designed structures were synthesized by Intefrated DNA Technologies</p>

     <legend><a name="exp18.51">18.51 Isolation of flagella from WT3610</a></legend>

     <p>1 LB was inoculated with WT 3610 and incubated overnight at 37&deg;C.</p>

     <legend><a name="exp15.62">15.62 restriction digest of piGEM-005 SpeI</a></legend>

     <th scope="row">Cutsmart 10x</th>

     <th scope="row">SpeI</th>

<p>Incubation at 37&deg;C for 2h &ndash; Inactivation by heat shock at 85&deg; for 10  min.</p>

     <p>End concentration: 50 ng/ µL</p>

     <legend><a name="exp18.51">18.51 Nco/Bam & Nco/Xho digest of pet24d</a></legend>

     <th scope="row">Pet24d (80 ng/&micro;L)</th>

     <th scope="row">Cutsmart 10x</th>

     <th scope="row">NcoI</th>

     <th scope="row">BamHI</th>

     <th scope="row">XhoI</th>

     <p>End concentration: 25 ng/ µL pet-N/B & 15 ng/µL-N/X</p>

     <legend><a name="exp18.52">18.52 Isolation of flagella from WT3610</a></legend>

     <p>The preculture  was centrifuged at 4000 rpm and the pellet was resuspended in 33 mL Tris buffer  (pH 8.0) with 0,5% Brij-58. A stock solution of lysozyme with10 mg/mL was made.  330 &micro;L were added to the Tris buffer/ Buffer mix. The lysis was performed at 4&deg;C with a rotator until the pellet was completely solved which ca. 2-3h. DNase (5 &micro;g/ mL) in presence of 0,01M magnesium chloride were added and incubated for  half an hour at 4&deg;C in the rotator as well.</p>

     <p>After that the  suspension was centrifuged at 10000xg for 10 min. 80 &micro;L of the supernatant were  transferred into a 1,5 mL tube. The supernatant was then centrifuged at 87000xg  for 90min.</p>

     <p>The pellet was  resuspended in 10 mL standard saline citrate (0,01M trisodium citrate &amp;  0,1M sodium chloride, pH 7,3) on ice and 80 &micro;L taken as well. For fractioning 2  g of ammonium sulfate (20%) were added until precipitation could be seen.</p>

     <p>After some  minutes of resting the suspension was centrifuged at 20000 rpm for 15 min. The  pellet was then resuspended in 2 mL of standard saline citrate buffer. After  taking a sample of 80 &micro;L the 4 samples ware mixed with 20 &micro;L SDS-loading buffer  each and analysed on an SDS-PAGE gel.</p>

     <p>The purified  filaments were frozen away in liquid nitrogen and then at -80&deg;C.</p>

     <p>The flagella purification was successful. Besides the flagellin the hook proteins are also in the samples but the smaller proteins were removed from the purified pellet.</p>

     <legend><a name="exp22.0">22. Cell culture assays</a></legend>

     <legend><a name="exp22.1">22.1 Splitting of Caco-2-cells</a></legend>

     <p>A culture flask of Caco-2-cells were received  from Dr. Hartmann Reifert (BMFZ). In order to let them grow the cells had to be  splitted due to a specific protocol. Caco-2-cells require DMEM (Dulbecco&rsquo;s  Modified Eagle Medium) with 20% FCS and L-Glutamine.</p>

     <p>A centrifuge was set on 4&deg;C.</p>

     <p>The PBS was aspirated with a glass pipette  until the supernatant was clear. After adding 1-2 mL 1x trypsin from the  opposite of the adherent cells the flask was incubated for 5-10 min at 37&deg;C  depending on how fast the cells come of from the ground. Under the microscope  the free floating cells were checked.</p>

     <p>The cells were transferred into a 15 mL falcon  and rinsed with 10 mL DMEM to collect all remaining cells in the flask. The 15  mL falcon was filled with DMEM and the culture spinned down at 1500 rpm&nbsp; for 5 min at 4&deg;C.</p>

     <p>The synthesized fragments by Integrated DNA technologies came as a dried 200ng DNA pellet. In order to use it as a PCR template the pellet was  centrifuged down and resuspended in 20 &micro;L Millipore to get an end concentration  of 10 ng/&micro;L as a Stock solution.</p>

     <p>0,5&nbsp; &micro;L were used as a PCR  template.</p>

</div>

     <p>Aim: Insertion of Hag-D2-Cup and Hag-D2-Strep into piGEM-005</p>

    </div>

    <table width="100%" border="1">

     <th scope="row">piGEM-005 SpeI<br />

<p>Incubation was done &nbsp;at 50&deg;C for  1h with following transformation into <em>E.Coli  XL1-Blue, </em>plated out on LB-Amp plates and incubated overnight at 37&deg;C.</p>

     <p>In order to check the successful integration of D2-Cup and D2-Strep clones were picked for cPCR and transferred on a LB-Amp master plate. As primers Flo96 (D23-fw) and Flo97 (D23-v) were used.</p>

     <th scope="row">Phusion</th>

             <td>3 min</td>

         <p>The gel shows that clone 2 from the Gibson Hag-D2-Cup clones and clones  3 &amp; 4 from the Gibson Hag-D2-Strep clones contain the integrated plasmid  constructs. All 3 clones were picked for a miniprep in used for inoculation of  10 mL LB-Amp. Incubation was done overnight at 37&deg;C. </p>

         <p><strong>The new  constructs were labled with piGEM-026 (pMAD-Hag-D2-Cup) and piGEM-027  (pMAD-Hag-D2-Strep).</strong></p>

     <p>5 mL of LB  were inoculated with Bacillus WT3610 from an LB plate and incubated at 37&deg;C  overnight.</p>

     <legend><a name="exp15.66">15.66 Transformation of competent WT3610</a></legend>

     <p>Aim: transformation of plasmid into Bacillus subtilis WT3610</p>

     <p>100 &micro;L of overnight culture were added to 10 mL of MNGE-Medium and  incubated till an OD of 1,1-1,3 at 37&deg;C which could take 4-5h.</p>

     <p>After reaching OD of 1,1-1,3 2 x 400 &micro;L of the culture were transformed  with 1,5 &micro;g plasmid (piGEM-026 &amp; -027). After 1h incubation at 37&deg;C 100 &micro;L  Expression mix were added and incubated for 1h as well.</p>

     <legend><a name="exp13.72">13.72 Restriction of Nose plasmids with EcoRV</a></legend>

     <p>Aim: check if amyE and cat are still in plasmid, since B. subtilis could not successfully be transformed with the plasmids yet</p>

     <p>All Nose-plasmids (iGEM002-004 and 007-015) were restrictes with EcoRV to check if amyE and cat are still present in these plasmids, since they could not be transformed into B. subtilis successfully.</p>

     <legend><a name="exp13.72">13.72 Restriction of Nose plasmids with EcoRV - continuation</a></legend>

     <p>The samples were mixed with 2 µl of 5x Loading dye and 8 µl of it was loaded on a 1% agarose gel.</p>

     <p>All but plasmids piGEM004 and piGEM011 show the expected bands of ca 2000 and 4000 bp.</p>

     <p>The plasmids were transformed into Bacillus  subtilis and incubated at 30&deg;C.</p>

     <p>Aim: Bacillus subtilis pMad Trafo mit D2-Strep and D2-Cup</p>

     <p>Next step inoculate overnight culture from the x-gal plate with 3 ml LB-MLS.</p>

     <p>As the cultures were  not that blue (thin or old plate) wildtype cultures were inoculated for a new  transformation tomorrow. Therefore the plasmids piGEM-026 and -027 were prepped  from frozen pellets. </p>

     <p>Bacillus subtilis pMad Trafo mit D2-Strep and D2-Cup</p>

     <p>For the experimental procedure see the Materials section below. Anyway, two transformations are running currently that will be refered to as ‘old’ and ‘new’ transformation from now on.</p>

     <p>For the old transformation the first temperature  shift was performed in LB-MLS medium. Culture was plated in LB-MLS-X-Gal plates  and incubated at 42&deg;C over night.</p>

     <p>The new transformation was started with a culture  grown in MNGE medium, inoculated with a wildtype overnight culture. The culture  was grown until an optical density of 1,2 that is normally reached after 4-5h.  Strangly the culture reached this OD after almost 7h today. Plasmids (1.5&micro;g) piGEM026 and -027 were  transformed and the protocol was followed as described below.</p>

     <p>Bacillus subtilis pMad Trafo mit D2-Strep and D2-Cup</p>

     <p>New trafo, no colonies so far, further incubation.</p>

     <p>Old trafo 2nd temperature shift of hopefully positive colonies (only light blue).

</p>

     <p>Bacillus subtilis pMad Trafo mit D2-Strep and D2-Cup</p>

     <p>The blue/ white screening showed positive transformed blue clones from  the new transformation.&nbsp; 3 piGEM026 and -027 clones of different morphology  per plate were picked and used for inoculation of LB-MLS (4 mL LB, 4 &micro;L  Lincomycin, 4 &micro;L Erythromycin). Incubation was carried out overnight at 30&deg;C  with the cultures.<strong> </strong></p>

     <p>Aim: The flanks have to be amplified for a fusion PCR with the Killswitch modules in order to integrate them into the amyE and the lacA locus of Bacillus subtilis after cloning into pMAD</p>

     <p>Primers arrived and have been dissolved in Millipore water, dilution 1:10. Q5 Master Mix was used for the following PCRs to create the flanks of the killswitch parts I-III:</p>

     <th scope="col">Fragement</th>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

     <td>&nbsp;</td>

<p>AmyE Flank 1 (Primer  46/34 and 47/35)<br />

      <table width="100%" border="1">

     <th scope="col">amyE FlankI</th>

     <th scope="col">amyE FlankII</th>

     <th scope="col">lacA FlankI</th>

     <th scope="col">lacA FlankII</th>

     <th scope="col">amyE-yvyd FlankII</th>

     <th scope="row">Template  (B.s gDNA)</th>

         <p>Gel photo: all bands like expected (500 /1000 bp) </p>

     <p>Aim: First heat shock – integration of  pMAD-Insert into Bacillus chromosome via flanks</p>

     <p>The synthesized fragments by Integrated DNA technologies came as a dried 200ng DNA pellet. In order to use it as a PCR template the pellet was  centrifuged down and resuspended in 20 &micro;L Millipore to get an end concentration of 10 ng/&micro;L as a Stock solution.</p>

</div>

     <p>One blue colony per diluted piGEM026  and -027 clone was used to inoculate 4 mL LB. The cultures were incubated at 30&deg;C  for 6h and afterwards for 3h at 42&deg;C.</p>

     <p>Dilutions from 10-5 to 10-6 were plated out on&nbsp; X-Gal plates WITHOUT MLS selection. The  positive clones should not contain the resistance inside the backbone as well  as the galactosidase. The plates were incubated at 42&deg;C overnight. Some clones  (piGem027.1 and one of 27.2) did not grow and will be inoculated again. They  will be inoculated in LB-MLS for the first temperature shift tomorrow.</p>

     <legend><a name="exp22.3a">22.3 Transformation of competent DH5a with pMAD</a></legend>

     <p>Aim: Gain E.coli on plate for mini preps of pMad</p>

     <p>Standard heat shock transformation protocol was  followed, incubation over night at 37&deg;C. pMad from the plasmid box was used for  transformation.</p>

     <legend><a name="exp22.4">22.4 Restriction of pMad with NcoI and BamHI over night</a></legend>

     <th scope="row">Cutsmart 10x</th>

     <th scope="row">NcoI</th>

     <th scope="row">BamHI</th>

     <p>From the dilution plates was one WHITE clone picked and transferred on a  Master X-Gal Plate as well as on a MLS plate so that clones were proven for the  right integration of the insert although flipping out the pMAD backbone.</p>

     <legend><a name="exp22.5">22.5 Fusion PCR </a></legend>

     <p>Aim: Assembly of Killswitch modules I & II with amyE and lacA flanks</p>

     <th scope="row">amyE flank I</th>

     <th scope="row">amyE flank II</th>

     <th scope="row">lacA flank I</th>

     <th scope="row">lacA flank II</th>

     <th scope="row">amyE yvyd flank II</th>

     <th scope="col">amyE KS I</th>

     <th scope="col">lacA KS II</th>

     <th scope="row">amyE  flank I ( 44,6 ng/&micro;L)</th>

     <th scope="row">amyE  flank II (40,3 ng/&micro;L)</th>

     <th scope="row">lacA  flank I (36,8 ng/&micro;L)</th>

     <th scope="row">lacA  flank II (39,6 ng/&micro;L)</th>

     <th scope="row">Phusion</th>

         <p>Gel analysis:</p>

        <p>no bands</p>

     <legend><a name="exp18.53">18.53 PCR amplification of StrepDARPidin into pet24d</a></legend>

     <p>Aim: amplification of the StrepDARPidin for cloning into the expression vector pet24d for protein purification and overproduction in E.Coli BL21</p>

     <p>The synthesized fragments by Integrated DNA technologies came as a dried  200ng DNA pellet. In order to use it as a PCR template the pellet was  centrifuged down and resuspended in 20 &micro;L Millipore to get an end concentration  of 10 ng/&micro;L as a Stock solution.</p>

         <p>Both attempts had a  concentration of 380 ng/ &micro;L.</p>

     <legend><a name="exp18.54">18.54 restriction of amplified of StrepDARPidin for cloning into pet24d</a></legend>

     <p>Aim: digest with NcoI and XhoI of the StrepDARPidin PCR product for cloning into the expression vector pet24d </p>

     <p>The PCR product was cut with NcoI and XhoI to get the restriction sites for cloning into pet24d Nco/Xho cut.</p>

     <th scope="row">Cutsmart 10x</th>

     <th scope="row">NcoI</th>

     <th scope="row">XhoI</th>

     <legend><a name="exp18.55">18.55 ligation of restricted StrepDARPidin for cloning into pet24d</a></legend>

     <p>Aim: ligation of StrepDARPidin PCR product with the expression vector pet24d </p>

     <p>The PCR product was ligated into cut pet24d Nco/Xho. Two attempts were made for a transformation into E. Coli XL1-Blue and BL21.</p>

     <th scope="row">Nco/Xho qStrepDARPidin (64 ng/ &micro;L)</th>

     <th scope="row">Pet24d Nco/Xho (15  ng/&micro;L)</th>

<p>Incubation for 1,5h at room temperature with heat shock at 85&deg;C for 10 min. The 20 &micro;L from ligation I were transformed into E.Coli XLI-Blue, 10 &micro;L from Ligation II were transformed into <em>E.Coli &nbsp;BL21 </em>and the rest of Ligation II into  Xl1-Blue as welland selected on  LB-Canamycin plates.</p>

     <p>All clones on the master plate grew on x-gal  plates but were MLS sensitive and could be seen as positive. In order to check  the correct insertion of D2-Cup an D2-Strep into the Bacillus subtilis genome  the clones were cooked in 100 &micro;L 1x PBS at 95&deg;C for 10 min and used for colony  PCR. Because of the repetition of the temperature shifts with clones 27.1.1,  27.1.2, 27.1.3 yesterday and today and 27.2.3, 6 clones from 26.1 -26.3, 27.2.1  &amp; 27.2.2 were picked for the cPCR (30 attempts).</p>

     <th scope="row">Phusion</th>

         <p> Gel analysis:<br />no bands</p>

<p>The grown clones from the ligation the day before were inoculated for miniprep in the morning and then checked via cPCR with primers iGEM-032 and -033.</p>

     <th scope="row">Phusion </th>

         <img src="https://static.igem.org/mediawiki/2014/a/a3/MR_2014-08-26_18.56.jpg" width="30%" />

         <p>The gel shows that the clones I  2-6, II 1-6 and III 2, 3, 4 and 6 are positive due to their band at ca. 900 bp.  The other bands might be plasmid which was used as template.</p>

         <p>The clones I6, II3, III3 were transformed into E.Coli BL21(DE3) and selected on LB-Can plates. III4 and III6  were already on a master plate. The clones were inoculated for miniprep and sent for sequencing.</p>

     <legend><a name="exp22.5">22.5 Fusion PCR Attempt 3</a></legend>

<p>Aim: Fusion of amyE and lacA flanks to the killswitch fragments</p>

     <th scope="row">amyE flank I ( 44,6 ng/&micro;L)</th>

     <th scope="row">amyE flank II (40,3 ng/&micro;L)</th>

     <th scope="row">lacA flank I (36,8 ng/&micro;L)</th>

     <th scope="row">lacA flank II (39,6 ng/&micro;L)</th>

     <th scope="row">Phusion</th>

             <td>3 min</td>

   <p>Gel analysis: no bands</p>

<p>Aim: Amplification of Cu- and Ag promotor sequences out of the chromosomal DNA from Bacillus Subtilis</p>

     <th scope="row">Template (cDNA B.s.)</th>

     <th scope="row">Phusion</th>

             <td>4min</td>

         <p>The gel shows positive bands at ca. 100 bp and 250 bp which was like expected.</p>

     <legend><a name="exp13.74">13.74 NcoI/ SacI digest of piGEM-002</a></legend>

     <th scope="row">NcoI</th>

     <th scope="row">SacI</th>

     <th scope="row">Cutsmart Buffer 10x</th>

     <legend><a name="exp13.75">13.75 Ligation of Nco/Sac cut piGEM-002 with annealed oligos containing promoter sequences</a></legend>

<p>In order to test our nose system with new promotor sequences oligos were designed and annealed by heating up water and letting it cool down with the oligo pairs iGEM-59/60, -61/62, - 63/64 so that the individual fragments were able to anneal with overlaps to the Nco/Sac sites.</p>

<p>The attempts were  incubated at room temperature for an hour and transformed into <em>E. Coli XL1-Blue</em>, plated out on LB-Amp.</p>

     <legend><a name="exp13.76">13.76 Gibson assembly of Nco/Sac piGEM-002 & Cu/ Ag promotor</a></legend>

<p>The attempts were  incubated at 50&deg;C for an hour and transformed into <em>E. Coli XL1-Blue</em>, plated out on LB-Amp.</p>

     <legend><a name="exp22.3b">22.3 repeated Amplification of Killswitch modules I and II</a></legend>

<p>Aim: Increase the amount of modules for further purification, since Fusion PCR did not work “quick and dirty”</p>

     <th scope="row">Phusion polymerase</th>

     <legend><a name="exp22.3c">22.3 repeated amplification of killswitch flanks</a></legend>

     <th scope="col">amyE FlankI</th>

     <th scope="col">amyE FlankII</th>

     <th scope="col">lacA FlankI</th>

     <th scope="col">lacA FlankII</th>

     <th scope="col">amyE-yvyd FlankII</th>

     <th scope="row">Phusion polymerase</th>

     <img src="https://static.igem.org/mediawiki/2014/0/07/MR-2014-08-27_22.3.jpg" width="30%" />

     <legend><a name="exp13.1">18.57 repeated PCR amplification of StrepDARPidin into pet24d</a></legend>

<p>Aim: amplification of the StrepDARPidin for cloning into the expression vector pet24d for protein purification and overproduction in E.Coli BL21</p>

<p>The synthesized fragments by Integrated DNA technologies came as a dried  200ng DNA pellet. In order to use it as a PCR template the pellet was  centrifuged down and resuspended in 20 &micro;L Millipore to get an end concentration  of 10 ng/&micro;L as a Stock solution.</p>

<p>0,5&nbsp; &micro;L were used as a PCR  template. The PCR fragment should be ca. 900 bp long. </p>

     <th scope="row">Template 2: Hag-KpnI (10 ng/ &micro;L)</th>

     <th scope="row">Phusion</th>

</div>

     <legend><a name="exp18.56b">18.56 Expression-Test with transformed E.Coli BL21 (DE3)</a></legend>

<p>Aim: Checking the overexpression of pet24d-StrepDARPidin</p>

     <p>The gel  did not show any signs of over expression so that lactose was chosen to test  the expression. New test expression cultures (I6, II3, III3, III4, III6)&nbsp; were made with 100 mL LB-Can and 5 mL lactose  (6,25 g/ 25 mL) per culture. Incubation was performed overnight at 30&deg;C.</p>

     <td>piGEM-028 I6(pet-StrepDARPidin)</td>

     <td>piGEM-028 III3  (pet-StrepDARPidin)</td>

     <legend><a name="exp18.561">18.56 Expression-Test with transformed E.Coli BL21 (DE3)</a></legend>

<p>Aim: Checking the overexpression of pet24d-StrepDARPidin</p>

<img src="https://static.igem.org/mediawiki/2014/d/df/MR_2014-08-27_18.56.jpg" width="30%" />

     <legend><a name="exp18.57">18.57 His-bead purification of pellet from E.Coli BL21</a></legend>

<p>Aim: Checking the overexpression of pet24d-StrepDARPidin</p>

<p>The 100 mL culture from I6 &amp;  III3 were centrifuged at 4000 rpm for 10 min in 2x50 mL falcons. The pellets  were washed in 10 mL buffer A and cracked with the microfluidizer. After that  the suspension was centrifuged at 20000 rpm for 20 min/ 4&deg;C. The supernatant  was ransferred into a 50 mL falcon.</p>

<p>After that the suspension was  centrifuged or 5 min at 4000 rpm so that the pellet could be resuspended in 500  &micro;L Buffer A after discarding the supernatant. The 500 &micro;L were transferred into a1,5 mL tube and centrifuged at 4000 rpm for washing. After discarding the  supernatant the pellet was washed again with 500 &micro;L Buffer A. After a second  centrifugation at 4000 rpm the supernatant was discarded, the pellet  resuspended in 200 &micro;L Buffer A and centrifuged at 13000 rpm to destroy the  Ni-bead &ndash; protein interaction.</p>

<p>40 &micro;L of the supernatant from  clone I6 and III3 were added with 10 &micro;L SDS-PAGE Buffer and analysed on the  SDS-Gel.</p>

     <legend><a name="exp22.3d">22.3 repeated amplification of killswitch flanks</a></legend>

<p>Aim: The flanks have to be amplified for a fusion PCR with the Killswitch modules in order to integrate them into the amyE and the lacA locus of Bacillus subtilis after cloning into pMAD, yield higher amount of fragments for purification and FusionPCR.</p>

     <th scope="col">amyE FlankI</th>

     <th scope="col">amyE FlankII</th>

     <th scope="col">lacA FlankI</th>

     <th scope="col">lacA FlankII</th>

     <th scope="col">amyE-yvyd FlankII</th>

     <th scope="row">Template (B.s gDNA)</th>

             <td>3 min</td>

     <legend><a name="exp22.3e">22.3 repeated Amplification of Killswitch modules I and II</a></legend>

<p>Aim: Increase the amount of modules for further purification, since Fusion PCR did not work “quick and dirty”. Q5 was used and gDNA since the previously amplified modules did not work as template yesterday.</p>

             <td>3 min</td>

             <td>3 min</td>

         <p>The expected bands could be seen for the flank I of amyE and flank I and II of lacA. These bands were cut out and purified via a Gel Extraction kit, but the concentration was too low to work further.</p>

     <legend><a name="exp13.75">13.75 NcoI/ SacI digest of piGEM-002</a></legend>

<p>The already digested piGEM002 of 26.08. was nearly empty. To have some digested plasmid as backup a new restriction was carried out. piGEM002 was prepped today and used for the restriction.</p>

     <th scope="row">NcoI</th>

     <th scope="row">SacI</th>

     <th scope="row">Cutsmart Buffer 10x</th>

     <legend><a name="exp13.76">13.76 repeated Gibson assembly of Nco/Sac piGEM-002 & Cu/ Ag promotor</a></legend>

<p>Aim: assembling of Nco/Sac cut piGEM-002 with Cu/Aag promotor sequences</p>

<p>In order to test new Cu/ Ag promotor sequences the PCR fragments from 13.73 were used for a Gibson assembly.</p>

<p>The attempts were  incubated at 50&deg;C for an hour and transformed into <em>E. Coli XL1-Blue</em>, plated out on LB-Amp.</p>

     <legend><a name="exp13.77">13.77 repeated ligation of Nco/Sac cut piGEM-002 with annealed oligos containing promoter sequences</a></legend>

<p>The attempts were  incubated at room temperature for an hour and transformed into <em>E. Coli XL1-Blue</em>, plated out on LB-Amp.</p>

    <td>piGEM-028  I6(pet-StrepDARPidin)</td>

    <td>piGEM-028 III3  (pet-StrepDARPidin)</td>