Team:Freiburg/Project/toolkit

From 2013.igem.org

(Difference between revisions)

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 <p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/1"> Abstract & Intro </a></p>
+<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/crrna"> Targeting </a></p>
 <p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/effector"> Effectors </a></p>
 <p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/induction"> Effector Control </a> </p>
-<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/crrna"> Targeting </a></p>
+<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/modeling"> Modeling </a></p>
+<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/truncation"> Truncation </a></p>
 <p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/method"> uniBAss </a></p>
+<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/unibox"> uniBOX </a></p>
 <p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/toolkit" class="active"> Manual </a></p>
-<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/modeling"> Modeling </a></p>
+<p class="first_order"><a href="https://2013.igem.org/Team:Freiburg/Project/application" > Application </a></p>
 </div>
@@ Line 653: / Line 660: @@
 </ul>
-By the end of the routine you will get a personal manual. All you need to use the uniCAS toolkit
+By the end of the routine you will get a personal manual. All you need to do is using the uniCAS toolkit and follow the instructions. Best of all: The uniCAS toolkit is all open source and in iGEM standard!
+<br>
-will be described there. Best of all: The uniCAS toolkit is all open source and in iGEM standard!
+<!--
+<p><b>Finally ... does everybody know what time it is? It's tooltime!</b></p>
+Also have a look at Sigma Aldrich to order your oligos coding for the crRNAs: <br>
+<br>
+<a href="http://www.sigmaaldrich.com/germany.html"> <img src="https://static.igem.org/mediawiki/2013/0/01/SA_Logo_freiburg.jpg" width="300px"> </a>
+-->
 </div>
@@ Line 670: / Line 683: @@
 <div id="check-1" class="toHide" style="display:none">
 <img src="https://static.igem.org/mediawiki/2013/6/6e/Activation.png">
-<p> Choose an effector to activate your genes. Click <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/effector#activation"> here </a> to see the functional tests of the different activation effectors. </p>
+<p> Choose an effector to activate your genes. Click <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/effector#activation"> here</a> to see the functional tests of the different activation effectors. </p>
 <label><input id="rdb4" type="radio" name="toggler_two" value="3" onClick="pageScroll()"/>VP16 (recommended) </label>
 <!-- <label><input id="rdb5" type="radio" name="toggler_two" value="4" onClick="pageScroll()"/> ?????? </label> -->
@@ Line 677: / Line 690: @@
 <div id="check-2" class="toHide" style="display:none">
 <img src="https://static.igem.org/mediawiki/2013/d/da/Repression.png">
-<p> Effectively repress your genes using KRAB or G9A as functional effector. <br> Click <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/effector#repression"> here </a> to see the functional tests of the different activation effectors. </p>
+<p> Effectively repress your genes using KRAB or G9a as functional effector. <br> Click <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/effector#repression"> here</a> to see the functional tests of the different activation effectors. </p>
 <div>
 <label><input id="rdb4" type="radio" name="toggler_two" value="5" onClick="pageScroll()"/>KRAB </label>
-<label><input id="rdb5" type="radio" name="toggler_two" value="6" onClick="pageScroll()"/> G9A </label>
+<label><input id="rdb5" type="radio" name="toggler_two" value="6" onClick="pageScroll()"/> G9a </label>
 </div>
 </div>
@@ Line 755: / Line 768: @@
 			<p id="h1">
-			Non inducible uniCAS Activator (Cas9-VP16 device)
+			Non inducible uniCAS Activator (dCas9-VP16 device)
 			</p>
 			<p>
-			You have chosen to activate a gene using a non inducible Cas9-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to activate a gene using a non inducible dCas9-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 773: / Line 786: @@
 					<td> 1 </td>
 					<td> BBa_K1150017 </td>
-					<td> CMV-HA-NLS-Cas9-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150017"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 780: / Line 793: @@
 					<td> 2 </td>
 					<td> BBa_K1150020 </td>
-					<td> CMV-HA-NLS-Cas9-L3-VP16-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150020"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 787: / Line 800: @@
 					<td> 3 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid) </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 798: / Line 811: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing a SV40 instead of a CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T.
 			</p>
@@ Line 820: / Line 833: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH<sub>2</sub>O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH<sub>2</sub>O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH<sub>2</sub>O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH<sub>2</sub>O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH<sub>2</sub>O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH<sub>2</sub>O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 840: / Line 853: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 854: / Line 867: @@
 			<ol>
 				<li> <b>Transfect</b> BBa_K1150020 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
-				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid togehter with BBa_K1150017 that has no effector.</li>
+				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.</li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150020 without any crRNA plasmid.</li>
@@ Line 860: / Line 873: @@
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/7/7c/1_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 888: / Line 901: @@
 			<p id="h1">
-			Red light inducible uniCAS Activator (Cas9-PIF6 & PhyB-VP16 devices)
+			Red light inducible uniCAS Activator (dCas9-PIF6 & PhyB-VP16 devices)
 			</p>
 			<p>
-			You have chosen to activate a gene using a red light inducible Cas9-PIF6 & PhyB-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to activate a gene using a red light inducible dCas9-PIF6 & PhyB-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 906: / Line 919: @@
 					<td> 1 </td>
 					<td> BBa_K1150025 </td>
-					<td> CMV-HA-NLS-Cas9-L3-PIF6-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150025"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 913: / Line 926: @@
 					<td> 2 </td>
 					<td> BBa_K1150026 </td>
-					<td> CMV-NLS-PhyB-L3-VP16-NLS-BGH </td>
+					<td> CMV:NLS-PhyB-L3-VP16-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150026"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 920: / Line 933: @@
 					<td> 3 </td>
 					<td> BBa_K1150020 </td>
-					<td> CMV-HA-NLS-Cas9-L3-VP16-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150020"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 927: / Line 940: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 939: / Line 952: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing a SV40 instead of a CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 962: / Line 975: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 982: / Line 995: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 995: / Line 1,008: @@
 			<p>
-			For red light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with 740 nm. This is the no-induction control. Before illuminating you have to put PCB in the wells. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
+			For red light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with 740 nm. This is the no-induction control. If not working in plant systems add 15µM of PCB prior to illumination and incubate for at least 1h. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
 			</p>
@@ Line 1,001: / Line 1,014: @@
 				<li> <b>Transfect</b> BBa_K1150025, BBa_K1150026 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150025, BBa_K1150026 without any crRNA plasmid.</li>
-				<li> <b>Target efficiency control:</b> Transfect BBa_K1150020 with the same crRNA Plasmids as in the first transfection.</li>
+				<li> <b>Target efficiency control:</b> Transfect BBa_K1150020 with the same crRNA plasmids as in the first transfection.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/2/2b/2_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,045: / Line 1,058: @@
 			<p id="h1">
-			UVB light inducible uniCAS Activator (Cas9-UVR8 & COP1-VP16 devices)
+			UVB light inducible uniCAS Activator (dCas9-UVR8 & COP1-VP16 devices)
 			</p>
 			<p>
-			You have chosen to activate a gene using a UVB light inducible Cas9-UVR8 & COP1-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to activate a gene using a UVB light inducible dCas9-UVR8 & COP1-VP16 device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 1,063: / Line 1,076: @@
 					<td> 1 </td>
 					<td> BBa_K1150029 </td>
-					<td> CMV-HA-NLS-Cas9-L3-UVR8-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150029"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,070: / Line 1,083: @@
 					<td> 2 </td>
 					<td> BBa_K1150030 </td>
-					<td> CMV-NLS-COP1-L3-VP16-NLS-BGH </td>
+					<td> CMV:NLS-COP1-L3-VP16-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150030"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,077: / Line 1,090: @@
 					<td> 3 </td>
 					<td> BBa_K1150020 </td>
-					<td> CMV-HA-NLS-Cas9-L3-VP16-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150020"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,084: / Line 1,097: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,096: / Line 1,109: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing a SV40 instead of a CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,119: / Line 1,132: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 1,139: / Line 1,152: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 1,152: / Line 1,165: @@
 			<p>
-			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
+			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm at 5 µE for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
 			</p>
@@ Line 1,158: / Line 1,171: @@
 				<li> <b>Transfect</b> BBa_K1150029, BBa_K1150030 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150029, BBa_K1150030 without any crRNA plasmid.</li>
-				<li> <b>Target efficiency control:</b> Transfect BBa_K1150020 with the same crRNA Plasmids as in the first transfection.</li>
+				<li> <b>Target efficiency control:</b> Transfect BBa_K1150020 with the same crRNA plasmids as in the first transfection.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/d/dd/3_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,209: / Line 1,222: @@
 			<p id="h1">
-			Non inducible uniCAS Repressor (Cas9-KRAB device)
+			Non inducible uniCAS Repressor (dCas9-KRAB device)
 			</p>
 			<p>
-			You have chosen to repress a gene using a non inducible Cas9-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to repress a gene using a non inducible dCas9-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 1,227: / Line 1,240: @@
 					<td> 1 </td>
 					<td> BBa_K1150017 </td>
-					<td> CMV-HA-NLS-Cas9-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150017"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,234: / Line 1,247: @@
 					<td> 2 </td>
 					<td> BBa_K1150022 </td>
-					<td> CMV-HA-NLS-Cas9-L3-KRAB-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,241: / Line 1,254: @@
 					<td> 3 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,252: / Line 1,265: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing a SV40 instead of a CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,275: / Line 1,288: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 1,295: / Line 1,308: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li> Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li> Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 1,309: / Line 1,322: @@
 			<ol>
 				<li> <b>Transfect</b> BBa_K1150022 (4 fold excess) with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
-				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid togehter with BBa_K1150017 that has no effector.</li>
+				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.</li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150022 without any crRNA plasmid.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/d/dc/4_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,341: / Line 1,354: @@
 			<p id="h1">
-			Red light inducible uniCAS Repressor (Cas9-PIF6 & PhyB-KRAB devices)
+			Red light inducible uniCAS Repressor (dCas9-PIF6 & PhyB-KRAB devices)
 			</p>
 			<p>
-			You have chosen to repress a gene using a non inducible Cas9-KRAB device. Therefore you have to order the
+			You have chosen to repress a gene using a non inducible dCas9-KRAB device. Therefore you have to order the
-following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our
+following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our
 plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
@@ Line 1,363: / Line 1,376: @@
 					<td> 1 </td>
 					<td> BBa_K1150025 </td>
-					<td> CMV-HA-NLS-Cas9-L3-PIF6-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150025">
@@ Line 1,372: / Line 1,385: @@
 					<td> 2 </td>
 					<td> BBa_K1150027 </td>
-					<td> CMV-NLS-PhyB-L3-KRAB-NLS-BGH </td>
+					<td> CMV:NLS-PhyB-L3-KRAB-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150027">
@@ Line 1,381: / Line 1,394: @@
 					<td> 3 </td>
 					<td> BBa_K1150022 </td>
-					<td> CMV-HA-NLS-Cas9-L3-KRAB-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022">
@@ Line 1,390: / Line 1,403: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034">
@@ Line 1,406: / Line 1,419: @@
 			All plasmids are optimized for expression in mammalian systems. The devices are also available containing
-an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a>
+a SV40 instead of a CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a>
-side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,435: / Line 1,448: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore
 mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes.
@@ Line 1,444: / Line 1,457: @@
 stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with
-ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use
+ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use
 DNA for the next step.</li>
@@ Line 1,451: / Line 1,464: @@
 into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x
-length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length
+length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length
 of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of
-Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with
+Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with
-ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the
@@ Line 1,483: / Line 1,496: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes
 cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it
-is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl
+is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl
-Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours.
+enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
 </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link"
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link"
 href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see
 above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify
 the gel slice and use DNA for the next step.</li>
@@ Line 1,522: / Line 1,535: @@
 plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with
-nm. This is the no-induction control. Before illuminating you have to put PCB in the wells. See our <a id="link"
+nm. This is the no-induction control. If not working in plant systems add 15µM of PCB prior to illumination and incubate for at least 1h. See our <a id="link"
 href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
@@ Line 1,539: / Line 1,552: @@
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/0/08/5_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,574: / Line 1,587: @@
 			<p id="h1">
-			UVB light inducible uniCAS Repressor (Cas9-UVR8 & COP1-KRAB devices)
+			UVB light inducible uniCAS Repressor (dCas9-UVR8 & COP1-KRAB devices)
 			</p>
 			<p>
-			You have chosen to repress a gene using a UVB light inducible Cas9-UVR8 & COP1-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to repress a gene using a UVB light inducible dCas9-UVR8 & COP1-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 1,592: / Line 1,605: @@
 					<td> 1 </td>
 					<td> BBa_K1150029 </td>
-					<td> CMV-HA-NLS-Cas9-L3-UVR8-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150029"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,599: / Line 1,612: @@
 					<td> 2 </td>
 					<td> BBa_K1150031 </td>
-					<td> CMV-NLS-COP1-L3-KRAB-NLS-BGH </td>
+					<td> CMV:NLS-COP1-L3-KRAB-NLS:BGH </td>
-					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150030"> order </a> </td>
+					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150031"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
 				</tr>
@@ Line 1,606: / Line 1,619: @@
 					<td> 3 </td>
 					<td> BBa_K1150022 </td>
-					<td> CMV-HA-NLS-Cas9-L3-KRAB-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH </td>
-					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150020"> order </a> </td>
+					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
 				</tr>
@@ Line 1,613: / Line 1,626: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,625: / Line 1,638: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,648: / Line 1,661: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 1,668: / Line 1,681: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 1,681: / Line 1,694: @@
 			<p>
-			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
+			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm at 5 µE for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
 			</p>
@@ Line 1,687: / Line 1,700: @@
 				<li> <b>Transfect</b> BBa_K1150029, BBa_K1150031 (4 fold excess) with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150029, BBa_K1150031 (4 fold excess)without any crRNA plasmid.</li>
-				<li> <b>Target efficiency control:</b> Transfect BBa_K1150022 (4 fold excess) with the same crRNA Plasmids as in the first transfection.</li>
+				<li> <b>Target efficiency control:</b> Transfect BBa_K1150022 (4 fold excess) with the same crRNA plasmids as in the first transfection.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/6/6d/6_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,716: / Line 1,729: @@
 			<p id="h1">
-			Non inducible uniCAS Histone Modificator for Repression (Cas9-G9a device)
+			Non inducible uniCAS Histone modifier for Repression (dCas9-G9a device)
 			</p>
 			<p>
-			You have chosen to repress a gene using a non inducible Cas9-G9a device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to repress a gene using a non inducible dCas9-G9a device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 1,734: / Line 1,747: @@
 					<td> 1 </td>
 					<td> BBa_K1150017 </td>
-					<td> CMV-HA-NLS-Cas9-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150017"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,741: / Line 1,754: @@
 					<td> 2 </td>
 					<td> BBa_K1150024 </td>
-					<td> CMV-HA-NLS-Cas9-L3-G9a-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH </td>
-					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022"> order </a> </td>
+					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150024"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
 				</tr>
@@ Line 1,748: / Line 1,761: @@
 					<td> 3 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,759: / Line 1,772: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,782: / Line 1,795: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 1,802: / Line 1,815: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 1,816: / Line 1,829: @@
 			<ol>
 				<li> <b>Transfect</b> BBa_K1150024 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
-				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid togehter with BBa_K1150017 that has no effector.</li>
+				<li> <b>Non-effector control:</b> Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.</li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150024 without any crRNA plasmid.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/1/1a/7_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,847: / Line 1,860: @@
 			<p id="h1">
-			Red light inducible uniCAS Histone Modificator for Repression (Cas9-PIF6 & PhyB-G9a devices)
+			Red light inducible uniCAS Histone modifier for Repression (dCas9-PIF6 & PhyB-G9a devices)
 			</p>
 			<p>
-			You have chosen to repress a gene using a non inducible Cas9-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to repress a gene using a non inducible dCas9-KRAB device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry</a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 1,865: / Line 1,878: @@
 					<td> 1 </td>
 					<td> BBa_K1150025 </td>
-					<td> CMV-HA-NLS-Cas9-L3-PIF6-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150025"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,872: / Line 1,885: @@
 					<td> 2 </td>
 					<td> BBa_K1150028 </td>
-					<td> CMV-NLS-PhyB-L3-G9a-NLS-BGH </td>
+					<td> CMV:NLS-PhyB-L3-G9a-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150028"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,879: / Line 1,892: @@
 					<td> 3 </td>
 					<td> BBa_K1150024 </td>
-					<td> CMV-HA-NLS-Cas9-L3-G9a-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH </td>
-					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022"> order </a> </td>
+					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150024"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
 				</tr>
@@ Line 1,886: / Line 1,899: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 1,898: / Line 1,911: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 1,921: / Line 1,934: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 1,941: / Line 1,954: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 1,954: / Line 1,967: @@
 			<p>
-			For red light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with 740 nm. This is the no-induction control. Before illuminating you have to put PCB in the wells. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
+			For red light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with 740 nm. This is the no-induction control. If not working in plant systems add 15µM of PCB prior to illumination and incubate for at least 1h. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
 			</p>
@@ Line 1,960: / Line 1,973: @@
 				<li> <b>Transfect</b> BBa_K1150025, BBa_K1150028 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150025, BBa_K1150028 without any crRNA plasmid.</li>
-				<li> <b>Target efficiency control:</b> Transfect BBa_K1150024 with the same crRNA Plasmids as in the first transfection.</li>
+				<li> <b>Target efficiency control:</b> Transfect BBa_K1150024 with the same crRNA plasmids as in the first transfection.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/3/3f/8_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>
@@ Line 1,993: / Line 2,006: @@
 			<p id="h1">
-			UVB light inducible uniCAS Histone Modificator for Repression (Cas9-UVR8 & COP1-G9a devices)
+			UVB light inducible uniCAS Histone modifier for Repression (dCas9-UVR8 & COP1-G9a devices)
 			</p>
 			<p>
-			You have chosen to repress a gene using a UVB light inducible Cas9-UVR8 & COP1-G9a device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
+			You have chosen to repress a gene using a UVB light inducible dCas9-UVR8 & COP1-G9a device. Therefore you have to order the following plasmids from the <a id="link" href="http://parts.igem.org/Main_Page"> iGEM parts registry </a>. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).
 			</p>
@@ Line 2,011: / Line 2,024: @@
 					<td> 1 </td>
 					<td> BBa_K1150029 </td>
-					<td> CMV-HA-NLS-Cas9-L3-UVR8-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150029"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>
@@ Line 2,018: / Line 2,031: @@
 					<td> 2 </td>
 					<td> BBa_K1150031 </td>
-					<td> CMV-NLS-COP1-L3-G9a-NLS-BGH </td>
+					<td> CMV:NLS-COP1-L3-G9a-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150031"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 2,025: / Line 2,038: @@
 					<td> 3 </td>
 					<td> BBa_K1150022 </td>
-					<td> CMV-HA-NLS-Cas9-L3-G9a-NLS-BGH </td>
+					<td> CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH </td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150022"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 2,032: / Line 2,045: @@
 					<td> 4 </td>
 					<td> BBa_K1150034 </td>
-					<td> crRNA - plasmid </td>
+					<td> RNAimer - plasmid (crRNA - plasmid)</td>
 					<td> <a id="link" href="http://parts.igem.org/partsdb/get_part.cgi?part=BBa_K1150034"> order </a> </td>
 					<!--<td> <a id="link" href=""> genebank </a> </td>-->
@@ Line 2,044: / Line 2,057: @@
 			<p>
 			Note: <br>
-			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts </a> side). This system was tested mainly in CHO-K1, HEK-293T and HeLa cells.
+			All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our <a id="link" href="https://2013.igem.org/Team:Freiburg/parts"> parts</a> side). This system was tested mainly in CHO-K1 and HEK-293T cells.
 			</p>
@@ Line 2,067: / Line 2,080: @@
 			<ol>
-				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligo to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
+				<li> <b>Oligo annealing:</b> Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.</li>
-				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exact 3 hours at 37° C. Load digest on a gel and cut the DNA band (2900 bp) out. Purify the gel slice and use DNA for the next step.</li>
+				<li> <b>Digest plasmid BBa_K1150034 with Bbs1:</b> The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.</li>
-				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng Bacbbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 Ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should incubate for 30 minutes at room temperature.</li>
+				<li> <b>Ligate crRNAs (step 1) into Bbs1 cut backbone:</b> The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone)  x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
 			</ol>
@@ Line 2,087: / Line 2,100: @@
 			<ol>
-				<li> <b>Digest first crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences in one plasmid. Therefore mix about 500 ng Backbone with 1 µl Enzyme 1 and 1 µl Enzyme 2, add an appropriate amount of compatible buffer and fill up to approximate 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
+				<li> <b>First of all digest crRNA plasmid</b> with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours. </li>
-				<li> <b>Digest second crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
+				<li> <b>Secondly digest crRNA plasmid</b> with PstI and XbaI. Using the <a id="link" href="http://parts.igem.org/Help:Assembly/3A_Assembly">BioBrick Assembly method</a>, this is your insert (procedure see above).</li>
-				<li>  Load digests on a gel and cut the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
+				<li>  Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.</li>
 				<li> <b>Ligate</b> the insert in 3 molar excess into the backbone (formular see paragraph above).</li>
 				<li> <b>Transform</b> 3-5 µl of the mix following <a id="link" href="https://2013.igem.org/Team:Freiburg/protocols#Transformation">standard protocol</a>. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).</li>
@@ Line 2,100: / Line 2,113: @@
 			<p>
-			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
+			For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm at 5 µE for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our <a id="link" href="https://2013.igem.org/Team:Freiburg/Project/induction#light">light induction project page</a>.
 			</p>
@@ Line 2,106: / Line 2,119: @@
 				<li> <b>Transfect</b> BBa_K1150029, BBa_K1150032 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid) </li>
 				<li> <b>Off target control:</b> Transfect BBa_K1150029, BBa_K1150032 (4 fold excess)without any crRNA plasmid.</li>
-				<li> <b>Target efficiency control:</b> Transfect BBa_K1150024 with the same crRNA Plasmids as in the first transfection.</li>
+				<li> <b>Target efficiency control:</b> Transfect BBa_K1150024 with the same crRNA plasmids as in the first transfection.</li>
 			</ol>
-<form> <a href="javascript:window.print()"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a> </form>
+<a href="https://static.igem.org/mediawiki/2013/3/32/9_manual_pdf_freiburg.pdf"> <img src="https://static.igem.org/mediawiki/2013/9/9d/Printknopf_freiburg_13.png" width="100px" border="0"  style="margin-left:350px; margin-top: 50px;" alt=""> </a>
 		</div>

Latest revision as of 00:59, 29 October 2013

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The uniCAS toolkit - Customize your experiments!

You want to have a maximum of activation or repression of your genes by a minimal effort? Then you have to use the uniCAS toolkit provided by the iGEM team Freiburg 2013. All you have to do is:

Click yourself through the routine below
Order the appropriate plasmids and oligos
Conduct a minimal of cloning
Start your personalized experiment

By the end of the routine you will get a personal manual. All you need to do is using the uniCAS toolkit and follow the instructions. Best of all: The uniCAS toolkit is all open source and in iGEM standard!

Activation

Repression

Choose an effector to activate your genes. Click here to see the functional tests of the different activation effectors.

VP16 (recommended)

Effectively repress your genes using KRAB or G9a as functional effector.
Click here to see the functional tests of the different activation effectors.

KRAB G9a

Effectively activate your genes using VP16 as functional effector.

No Induction Red light induction

UV light induction

Effectively repress your genes using KRAB as functional effector.

No Induction Red light induction UV light induction

Effectively repress your genes using KRAB as functional effector.

No Induction Red light induction

UV light induction

Effectively repress your genes using G9a as functional effector.

No Induction Red light induction

UV light induction

Non inducible uniCAS Activator (dCas9-VP16 device)

You have chosen to activate a gene using a non inducible dCas9-VP16 device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150017	CMV:HA-NLS-dCas9-NLS:BGH	order
2	BBa_K1150020	CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH	order
3	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Note:
All plasmids are optimized for expression in mammalian systems. The devices are also available containing a SV40 instead of a CMV promotor (have a look at our parts side). This system was tested mainly in CHO-K1 and HEK-293T.

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

It will generate possible target sites and the appropriate oligos. Order the oligos by the company of your choice. We recommend to test several different loci to target your gene of interest because the efficiency of different crRNA-loci can differ.

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH₂O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH₂O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH₂O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150020 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Non-effector control: Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.
Off target control: Transfect BBa_K1150020 without any crRNA plasmid.

Red light inducible uniCAS Activator (dCas9-PIF6 & PhyB-VP16 devices)

You have chosen to activate a gene using a red light inducible dCas9-PIF6 & PhyB-VP16 device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150025	CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH	order
2	BBa_K1150026	CMV:NLS-PhyB-L3-VP16-NLS:BGH	order
3	BBa_K1150020	CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

For red light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 660 nm for 48 hours. This is the red light induced plate. The other plate will be illuminated with 740 nm. This is the no-induction control. If not working in plant systems add 15µM of PCB prior to illumination and incubate for at least 1h. See our light induction project page.

Transfect BBa_K1150025, BBa_K1150026 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150025, BBa_K1150026 without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150020 with the same crRNA plasmids as in the first transfection.

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UVB light inducible uniCAS Activator (dCas9-UVR8 & COP1-VP16 devices)

You have chosen to activate a gene using a UVB light inducible dCas9-UVR8 & COP1-VP16 device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150029	CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH	order
2	BBa_K1150030	CMV:NLS-COP1-L3-VP16-NLS:BGH	order
3	BBa_K1150020	CMV:HA-NLS-dCas9-L3-VP16-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

For UVB light experiments transfect the following plasmid combinations on two different well plates. One plate will be illuminated with 311 nm at 5 µE for 24 hours. This is the UVB light induced plate. The other plate will be wrapped in aluminum foil. This is the no-induction control. See our light induction project page.

Transfect BBa_K1150029, BBa_K1150030 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150029, BBa_K1150030 without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150020 with the same crRNA plasmids as in the first transfection.

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Non inducible uniCAS Repressor (dCas9-KRAB device)

You have chosen to repress a gene using a non inducible dCas9-KRAB device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150017	CMV:HA-NLS-dCas9-NLS:BGH	order
2	BBa_K1150022	CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH	order
3	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150022 (4 fold excess) with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Non-effector control: Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.
Off target control: Transfect BBa_K1150022 without any crRNA plasmid.

Red light inducible uniCAS Repressor (dCas9-PIF6 & PhyB-KRAB devices)

No.	Biobrick	Device	Order
1	BBa_K1150025	CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH	order
2	BBa_K1150027	CMV:NLS-PhyB-L3-KRAB-NLS:BGH	order
3	BBa_K1150022	CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150025, BBa_K1150027 (4 fold excess) with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150025, BBa_K1150026 (4 fold excess) without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150022 (4 fold excess) with the same crRNA Plasmids as in the first transfection.

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UVB light inducible uniCAS Repressor (dCas9-UVR8 & COP1-KRAB devices)

You have chosen to repress a gene using a UVB light inducible dCas9-UVR8 & COP1-KRAB device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150029	CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH	order
2	BBa_K1150031	CMV:NLS-COP1-L3-KRAB-NLS:BGH	order
3	BBa_K1150022	CMV:HA-NLS-dCas9-L3-KRAB-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Note:
All plasmids are optimized for expression in mammalian systems. The devices are also available containing an SV40 instead of an CMV promotor (have a look at our parts side). This system was tested mainly in CHO-K1 and HEK-293T cells.

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150029, BBa_K1150031 (4 fold excess) with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150029, BBa_K1150031 (4 fold excess)without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150022 (4 fold excess) with the same crRNA plasmids as in the first transfection.

Non inducible uniCAS Histone modifier for Repression (dCas9-G9a device)

You have chosen to repress a gene using a non inducible dCas9-G9a device. Therefore you have to order the following plasmids from the iGEM parts registry. After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150017	CMV:HA-NLS-dCas9-NLS:BGH	order
2	BBa_K1150024	CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH	order
3	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150024 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Non-effector control: Transfect the appropriate crRNA - plasmid together with BBa_K1150017 that has no effector.
Off target control: Transfect BBa_K1150024 without any crRNA plasmid.

Red light inducible uniCAS Histone modifier for Repression (dCas9-PIF6 & PhyB-G9a devices)

No.	Biobrick	Device	Order
1	BBa_K1150025	CMV:HA-NLS-dCas9-L3-PIF6-NLS:BGH	order
2	BBa_K1150028	CMV:NLS-PhyB-L3-G9a-NLS:BGH	order
3	BBa_K1150024	CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands out (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150025, BBa_K1150028 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150025, BBa_K1150028 without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150024 with the same crRNA plasmids as in the first transfection.

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UVB light inducible uniCAS Histone modifier for Repression (dCas9-UVR8 & COP1-G9a devices)

You have chosen to repress a gene using a UVB light inducible dCas9-UVR8 & COP1-G9a device. Therefore you have to order the following plasmids from the iGEM parts registry . After receiving our plasmids, you will have to clone your target sequence into our crRNA plasmid (protocol see below).

No.	Biobrick	Device	Order
1	BBa_K1150029	CMV:HA-NLS-dCas9-L3-UVR8-NLS:BGH	order
3	BBa_K1150022	CMV:HA-NLS-dCas9-L3-G9a-NLS:BGH	order
4	BBa_K1150034	RNAimer - plasmid (crRNA - plasmid)	order

Design of the crRNA plasmid:

Use our crRNA design tool to design the crRNAs that are needed to target your gene of interest.

crRNA design tool

Oligo annealing: Anneal forward and reverse oligos to get the desired crRNA. Therefore mix 10 µl of 100 µM forward Oligo, 10 µl of 100 µM reverse Oligo and 80 µl of ddH2O. Heat the solution to 95° C for 5 minutes. Then turn off the heat block and let the solution cool down.
Digest plasmid BBa_K1150034 with Bbs1: The restriction enzyme Bbs1 should always be stored at -80° C. Mix about 500 ng of BBa_K1150034 with 1 µl of Bbs1, appropriate amount of buffer and fill up to 50 µl with ddH2O. Digest for exactly 3 hours at 37° C. Load the digest on a gel and cut out the DNA band (2900 bp). Purify the gel slice and use DNA for the next step.
Ligate crRNAs (step 1) into Bbs1 cut backbone: The insert (crRNAs) should be ligated into the backbone in 3 molar insert excess. Therefore use this formular: Required Volume of Insert = 3 x Volume(Backbone) x length(Insert) x concentration (Backbone) / [ length(Backbone) x concentration(Insert) ]. Use about 50 ng of backbone. The length of insert is always 30 basepairs. The length of the backbone is 2900 basepairs. You have to mix the appropriate amount of Backbone and the appropriate amount of Insert with 1 µl of T4 ligase and 2 µl of 10xT4 ligase buffer. Then fill up to 20 µl with ddH2O. This mix should be incubated for 30 minutes at room temperature.
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).

Now that you have created the desired crRNA plasmids it is possible to use them indiviually or fuse different crRNA loci together into one crRNA plasmid (recommended).

Design of a multiple target crRNA plasmid:

It is shown that multiple targeting of one gene of interest increases the efficiency of regulation. If you want to fuse different crRNA loci together into one plasmid use the following protocol:

First of all digest crRNA plasmid with PstI and SpeI in order to linearize it. Both enzymes cut in the suffix. Using the BioBrick Assembly method, it is possible to assemble multiple crRNA sequences into one plasmid. Therefore mix about 500 ng Backbone with 1 µl enzyme 1 and 1 µl enzyme 2, add an appropriate amount of compatible buffer and fill up to 30-50 µl. Incubate mix at 37° C for 2 hours.
Secondly digest crRNA plasmid with PstI and XbaI. Using the BioBrick Assembly method, this is your insert (procedure see above).
Load digests on a gel and cut out the DNA bands (Backbone 2900 bp, Insert 870 bp). Purify the gel slice and use DNA for the next step.
Ligate the insert in 3 molar excess into the backbone (formular see paragraph above).
Transform 3-5 µl of the mix following standard protocol. Pick clones, miniprep the plasmids and sequence it with pSB1C3 forward sequencing primer (sequence: GAGTGCCACCTGACGTCTAAGAAAC) and pSB1C3 reverse sequencing primer (sequence: CGCCTTTGAGTGAGCTGATACCGC).
These steps can be repeated various times. Using this method, you can engineer a plasmid with several crRNA targets!

Experimental design (recommendation for mammalian cell culture):

Transfect BBa_K1150029, BBa_K1150032 with all desired crRNA plasmids (seperate crRNA plasmid and/or multiple crRNAs plasmid)
Off target control: Transfect BBa_K1150029, BBa_K1150032 (4 fold excess)without any crRNA plasmid.
Target efficiency control: Transfect BBa_K1150024 with the same crRNA plasmids as in the first transfection.

Retrieved from "http://2013.igem.org/Team:Freiburg/Project/toolkit"

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