Difference between revisions of "Team:UCLouvain/Protocols"

Revision as of 01:58, 31 October 2017

iGEM UCLouvain Team iGEM UCLouvain Team

In the Lab

Protocols

DNA Gel electrophoresis

Materials

Agarose Powder
TAE buffer
Gel mould
Gel Tank
DNA ladder
DNA loading dye

Procedure

Prepare 0.8% agarose (w/v) solution in TAE buffer.
Heat until the agarose dissolve.
Pour into the gel mould and set a comb.
Wait for the gel to solidify.
Remove the comb and transfer into the gel tank. Fill with TAE buffer.
Fill the wells with DNA ladder and your samples mixed with corresponding amount of loading dye.
Run for 20-30 minutes at 120 V.

T4 Ligation

Materials

PCR tubes
T4 DNA Ligase (NEB)
T4 DNA Ligase buffer 10x
ddH20
Insert DNA

Procedure

Calculate insert to vector ratio with NEB calculator. Most common is 3:1.
Add the vector plasmid, the insert DNA, 2 µL of buffer, 1 µL of T4 ligase and enough ddH20 to reach 20 µL.
Gently mix by pipeting up and down.
For cohesive (sticky) ends, incubate at 16°C overnight or room temperature for 10 minutes. For blunt ends or single base overhangs, incubate at 16°C overnight or room temperature for 2 hours.
Heat inactivate at 65°C for 10 minutes.

Selection of the sgRNA and modification of pTarget

Introduction

This protocol cover the identification of a suitable N20 sequence and the modification of the pTarget plasmid. Protocol from S. Worms.

Procedure

1) Selection of the N20 sequence

Use Benchling's CRISPR tool, click on "Design and analyse guide"
Using the default settings (note: Doench et al.'s optimized scoring algorithm doesn't work for circular sequences such as bacterial chromosomes)
Select the target region and press (+)
Select the N20 with the higher On-target score.

2) Modification of pTarget

pTarget is currently available in two version, pTargetF with spectinomycin resistance and pTargetTet_pyrF and its derivatives with a tetracyclin resistance. They should behave identically.

1. Design a forward oligo to use for a QuickChange-like insertion of the N20 sequence. The sequence of the primer should be the following:

agctagctcagtcctaggtataatactagtNNNNNNNNNNNNNNNNNNNNgttttagagctagaaatagcaagttaaaa

where the Ns stands for your N20 sequence.

2. Amplify the pTarget backbone of your choice using the designed forward primer and the appropriate reverse primer (actagtattatacctaggactgagctagctg) using Q5 polymerase and the following conditions:

Temperature (°C)	Time
98	30 s
98	15 s	35 x
65	30 s
72	75 s
72	120 s
4	inf.

Media

Materials

NaCl
Tryptone
Yeast Extract
Na2HPO4
KH2PO4
NH4Cl
Glucose
Tyrosine
ddH20
CaSO5
MgSO4
Agar
Heat-resistant glass bottles

Procedure M9 medium

Make 10xM9 salts.
Mix the following in 500 mL H20 and sterilize by autoclave.

	Mass (g)
Na2HPO4	64 (Na2HPO4.7H2O)
KH2PO4	15
NaCl	2.5
NH4Cl	5

Make 1M CaCl2 stock solution The CaCl2 is sterilized separately to avoid formation of CaSO4 precipitate. Dissolve 5.592 g CaC2 to 50 mL H2O and sterilize by filtration or autoclaving.
Make 1M MgSO4 stock solution.
Make 20% glucose solution. Dissolve 10g of glucose in 50 mL H2O and sterilize by filtration. Do not autoclave. Dissolve 6.018 g of MgSO4 in 50 mL H2O and sterilize by filtration or autoclaving.
Make 5x tyrosine solution. Dissolve 0.25 g of tyrosine in 1L H2O and sterilize by filtration.
Sterilize water by autoclaving.
For 500 mL.

	M9	M9 + Tyr	M9 Agar	M9 Agar + Tyr
10x M9 salts	50	50	50	50
Agar (g)	0	0	7.5	7.5
H2O	445	345	445	345
Autoclave	No	No	Yes	Yes
M1 MgSO4	1	1	1	1
M1 CaSO4	0,1	0,01	0,01	0,1
20% glucose	5	5	5	5
Tyrosine	0	100	0	100

Procedure LB medium

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@@ Line 185: / Line 185: @@
 					<div class="section-title" style="text-align:left;float:left;width:100%;margin-bottom:0">
-						<p class="montserrat-text uppercase">Procedure</p>
+						<p class="montserrat-text uppercase">Procedure M9 medium</p>
 					</div>
@@ Line 191: / Line 191: @@
 						<li style="color:#999999;margin-left:20px;">Make 10xM9 salts.</li>
 						<li style="color:#999999;margin-left:20px;">Mix the following in 500 mL H20 and sterilize by autoclave.</li>
+                                      <table>
+                                               <tr>
+							<th style="padding:10px;border:1px solid #999;"></th>
+							<th style="padding:10px;border:1px solid #999;">Mass (g)</td>
+						</tr>
+						<tr>
+							<td style="padding:10px;border:1px solid #999;">Na2HPO4</td>
+							<td style="padding:10px;border:1px solid #999;">64 (Na2HPO4.7H2O) </td>
+						</tr>
+						<tr>
+							<td style="padding:10px;border:1px solid #999;">KH2PO4</td>
+							<td style="padding:10px;border:1px solid #999;">15 </td>
+						</tr>
+						<tr>
+							<td style="padding:10px;border:1px solid #999;">NaCl </td>
+							<td style="padding:10px;border:1px solid #999;">2.5 </td>
+						</tr>
+						<tr>
+							<td style="padding:10px;border:1px solid #999;">NH4Cl </td>
+							<td style="padding:10px;border:1px solid #999;">5 </td>
+						</tr>
+                                      </table>
 						<li style="color:#999999;margin-left:20px;">Make 1M CaCl2 stock solution The CaCl2 is sterilized separately to avoid formation of CaSO4 precipitate. Dissolve 5.592 g CaC2 to 50 mL H2O and sterilize by filtration or autoclaving.</li>
 						<li style="color:#999999;margin-left:20px;">Make 1M MgSO4 stock solution. </li>
@@ Line 268: / Line 298: @@
 					</ol>
+                                           <p class="montserrat-text uppercase">Procedure LB medium</p>
 				</div>
 				<div class="col-md-12">