Difference between revisions of "Team:DTU-Denmark/Experiments"

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<H2 style="text-align: left;margin-bottom:20px;">Protocols</H2>

<button id="resuspensionofdna" class="collapsible">Aspergillus niger protoplast</button>

This protocol is the adapted protocol from 223.

<li> 500 ml shake flasks </li>

<li> Solutions (APB, ATP, PCT, milli-Q, TM) </li>

<li> sterile tea spoon </li>

<li> mira cloth in funnel (sterile) </li>

<li> magnet stirrer </li>

<li> magnets </li>

<li> 50 ml sterile falcon tubes </li>

<li> 50 ml syringe </li>

<li> centrifuge for falcon tubes </li>

<li> 500 ml shake flasks </li>

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<li>Add 95 ml of YPD media supplemented with uridine to a shake flask and transfer 5 ml of the YPD media to a plate with A. niger. Collect conidia and spores from plate by carefully scraping off the conidia using a drigalski (the spores are hydrophobic and would therefore rather just fly around than actually get into suspension so be careful not to make a mess here). This should give a concentration of around 108 spores/100 ml. It is a good idea to make more than one shake flask at a time.</li>

<li>Add glucanex to APB to get a final concentration of 40 mg glucanex per ml APB and dissolve glucanex via gentle magnetic stirring and no heat.</li>

<li>Sterile filter 20 ml of APB+glucanex to each falcon tube using a 0.45 µm filter and a 50 ml syringe (there is a bit of resistance in the filter but that's ok).</li>

<li>Shake/incubate enzyme-mycelium mix at 30 °C, 150 RPM for 2-3 h.</li>

<li>Evaluate the number and quality of protoplasts in a microscope and discard a batch that is too diluted (i.e. < 105 protoplasts/ml). Approved protoplast solutions are then diluted by pouring APB up to 40 ml. and the tubess are balanced. Dilute Aspergillus transformation buffer (ATB) to 1/2x with sterile milli-Q H2O and carefully place 5 ml of this on top of the APB, creating an overlay. Centrifuge samples on rotor settings rotor code Sla-600TC; time: 13 min; Speed: 3000g; Temperatire: 16 °C, Acc: 2, Brake: 2 (NB! due to slow acc and brake, this takes forever!)</li>

<li>In the interphase between the two liquids, a halo of white slurry consisting of concentrated protoplasts should be observed. If there is cell wall debris mixed in with the protoplasts, that's ok. They can still be used. Withdraw the protoplasts with a pipette and wash them in a new falcon tube. Add ATB up to 40 ml and pellet the protoplasts at 3000g for 13 min (acc. 2, brake 2). Discard supernatant by decanting.</li>

<li>Resuspend protoplasts in 4 ml ATB to obtain concentrated solution.</li>

<button id="resuspensionofdna" class="collapsible">Aspergillus Transformation</button>

A quickoverview of the two different transformation protocols

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<li> Add at MOST 20 uL DNA ( or max 25% of protoplast volume) and 100 uL of protoplasts in a 50 mL falcon tube. </li>

<li> Add at MOST 25 uL (1500-5000 ng) DNA ( or max 25% of protoplast volume) and 100 uL of protoplasts in a 2 ml Eppendorf tube. 1 uL (100 ng) pac6 as positive control. </li>

<button id="proto3aassembly" class="collapsible">Bacterial Glycerol Stock</button>

Protocol for producing a glycerol stock of E. coli adapted by Jacob Mejlsted from <a href="https://www.addgene.org/protocols/create-glycerol-stock/" target="_blank">Addgene's protocol</a>.</i>

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<li>The stock can now be frozen at -80°C<br> If the stock is repeatedly thawed and frozen, it will reduce the shelf life of the culture</li>

This guide is to use the biolector. <br> NB! The machine is very slow - be patient!

<li> biolector</li>

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<li> Turn on the machine (bottom in the back, to the right) </li>

<li> Principal window ----> “Monitor” </li>

<li> When the lid opens, place the plate in the machine between the metal barrages - it should be firmly secured. </li>

<li> For create a new program go to second window “Start …” and follow the steps: </li>

<li> Choose new protocol and give it a name (if it is a warm-up program, specify it - the machine needs to warm up for 20-30 min before you add the plate) ----> Next. Names should be written as DDMMYYiGEM_*temperature*_XXXXX </li>

<li> Select the type of plate (MTP 48 wells FlowerPlate) ----> Next </li>

<li> Choose Layout (48 MTP) ----> Next </li>

<li> Select rpm (1000 rpm), temperature and humidity control, and manual (by defect) ----> Next </li>

<li> Select the filters to use (Biomass –> Gain 10, PFP –> Gain ?, GFP –> Gain ? ) ----> Next </li>

<li> Choose cycle time (30 min for the warm-up program and 3 min (more if several filters are addded) for our program) ----> Start </li>

<li> The machine will ask for refilling the deposit with water. Once done, press OK and the program will start running. Be sure to fill up water once a day. </li>

<li> When the running is finished, press Stop and save the file in the computer (in the machine, it is saved automatically). You need to press the 'update' button on the computer to get the updated data. </li>

<li> In the software go to “Data Management” and select “Transfer the data…”. You can create a new folder or select one already created and press create file. The file will be saved in the folder in cvs format. </li>

<li> Steril toothpicks/inoculation lops/pipette tips for transferring colonies </li>

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<li> Fill the first one (1) with 15 µl MQ water. </li>

<li> Transfer each colony to the eppendorf containing 15 µl water using a sterile toothpick, inoculation loop or autoclaved pipette tip. </li>

<li> Transfer 5 µl of the water from (1) to the empty (2) tube. This tube (2) is now for safekeeping in case the colony PCR shows that the transformant in question contains the correct insertion. </li>

<li>Set up a 25 µl reaction for each colony to be screened, as per NEB'S one-taq PCR protocol (see the <a href="https://international.neb.com/protocols/2012/10/11/onetaqdnapolymerasem0480" target="_blank">protocol</a>for troubleshooting).</li>

     <th class="tg-nzhz">25 µl reaction</th>

     <td class="tg-vqzh">5 µl</td>

     <td class="tg-rbwf">0,5 µl</td>

     <td class="tg-vqzh">0,5 µl</td>

     <td class="tg-rbwf">0,5 µl</td>

     <td class="tg-vqzh">0.125 µl</td>

     <td class="tg-rbwf">1 µl from the (1) tube</td>

     <td class="tg-vqzh">up to 25 µl</td>

<li> Prepare an O/N culture from the (2) tubes that have the correct insertions by adding 1 ml LB media to the tube, mixing it and transfer a W-tube containing 4 ml LB media. </li>

<button id="DpnIDigestion" class="collapsible">DpnI Digestion of PCR Products</button>

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<li>Add 1µL of DpnI to finished 50µL PCR reactions (or .5µL to 25µL reactions). Pipet or invert to mix.</li>

<button id="CompetentCell" class="collapsible">E.coli Competent Cell</button>

Adapted by Jacob Mejlsted & Kyle Rothschild from XXXX (ask Kyle)

<li> Spektrophotometer </li>

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<li> Minimum 100 mL 85 mM CaCl2 + 15% glycerol (v/v) </li>

<li>Freeze at -20 degC (after autoclaving)</li>

<li> Early in the morning, start cooling the Sorval centrifuge to 4 C </li>

<li> Grow the shakeflask culture at 37 C with shaking. Measure OD values of the sample every 20 minutes once the OD 600 value is above 0.2. </li>

<li> When OD 600 is between 0.3 and 0.4, put the cultures into an ice bath immediately, and swirl the shakeflash around in the cold water to cool culture. Chill the culture in the icewater for 20-30 minutes, occasionally swirling the cultures. </li>

<li> Centrifuge falcon tubes at 3000 x g for 15 min at 4 C (Spin #1 of 4) </li>

<li> Discard supernatant, and resuspend cells in 15 mL icecold 0.1 M MgCl2 </li>

<li> Centrifuge falcon tubes at 2000 x g for 15 min at 4 o C (Spin #2 of 4) </li>

<li> Discard the supernatant, and resuspend pellet in 40 mL icecold 0.1 M CaCl2 </li>

<li> Centrifuge falcon tubes at 2000 x g for 15 min at 4 C (Spin #3 of 4) </li>

<li> Discard supernatant, and resuspend pellet in 10 mL icecold 85 mM CaCl 2 + 15 % glycerol </li>

<li> Centrifuge falcon tubes at 1000 x g for 15 minutes at 4 C (Spin #4 of 4) </li>

<li> Resuspend pellet in 800 uL ice-cold 85 mM CaCl2 + 15 % glycerol </li>

<li> Immediately after cells are confirmed resuspended, aliquot 30 uL of the competent cell culture into the chilled PCR tubes </li>

<button id="GibsonAssemblyProtocol" class="collapsible">Gibson Assembly(combined)</button>

     <th class="tg-udlr">50 µl Reaction</th>

     <td class="tg-0pky">50 µl Reaction</td>

     <td class="tg-0pky">5 µl (1X)</td>

     <td class="tg-y698">1.0 µl (or 10 units)</td>

     <td class="tg-0pky">to 50 µl</td>

<li>Incubate at 37°C for 5–15 minutes (DpnI is Time-Saver qualified.)</li>

<li> Add 5 volumes Buffer PB to 1 volume of the PCR reaction and mix. If the color of the mixture is orange or violet, add 10 µl 3 M sodium acetate, pH 5.0, and mix. The color of the mixture will turn yellow </li>

<li> Place a QIAquick column in a provided 2 ml collection tube </li>

<li> To wash, add 750 µl Buffer PE to the QIAquick column centrifuge for 30–60 s. Discard flow-through and place the QIAquick column back into the same tube. </li>

<li> Centrifuge the QIAquick column once more in the provided 2 ml collection tube for 1 min to remove residual wash buffer. </li>

<li> Place each QIAquick column in a clean 1.5 ml microcentrifuge tube. </li>

<li> To elute DNA, add 50 µl Buffer EB (10 mM Tris·Cl, pH 8.5) or water (pH 7.0–8.5) to the center of the QIAquick membrane and centrifuge the column for 1 min. For increased DNA concentration, add 30 µl elution buffer to the center of the QIAquick membrane, let the column stand for 1 min and then centrifuge. </li>

<li>Store reactions at -20 °C or use in 1-2 uL per reaction for transformation</li>

 

<button id="ggBsaI" class="collapsible">Golden gate assembly with BsaI (Type IIs assembly)</button>

This protocol is made to assembly parts with TypeIIs enzyme BsaI HF v2. These parts will most probably have the standard Moclo overhangs. Made by PHS, adapted from <a href="https://static.igem.org/mediawiki/2017/e/e8/T--Evry_Paris-Saclay--protocol--pdf--gate.pdf" target="_blank">here</a>.

<li> Reciever plasmid (BsaI compatible like pGIA2P2o ) </li>

<li> MilliQ water </li>

<li> 10uL pipette tips </li>

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- MilliQ for a total volume of 20 µL. <br></li>

     <td class="tg-0pky">1: Activation of BsaI HF v2</td>

     <td class="tg-0pky">2: Activation of T4 ligase</td>

     <td class="tg-0pky">3: Inactivation BsaI HF v2</td>

     <td class="tg-y698">4: Inactivation T4 ligase</td>

     <td class="tg-0pky">5: Hold </td>

<button id="ggaSapI" class="collapsible">Golden gate assembly with SapI (Type IIs assembly)</button>

This protocol is made to assembly parts with TypeIIs enzyme SapI

<li> Reciever plasmid (Sap one compatible like ​Inaccessible DNA Sequence ) </li>

<li> MilliQ water </li>

<li> 10uL pipette tips </li>

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- MilliQ for a total volume of 20 µL. <br></li>

     <td class="tg-0pky">1: Activation of SapI</td>

     <td class="tg-vqzh">37&nbsp;&nbsp;°C </td>

     <td class="tg-0pky">2: Activation of T4 ligase</td>

     <td class="tg-vqzh">16&nbsp;&nbsp;°C </td>

     <td class="tg-0pky">3: Inactivation SapI</td>

     <td class="tg-y698">4: Inactivation T4 ligase</td>

     <td class="tg-0pky">5: Hold </td>

<button id="HifiDNAass" class="collapsible">Hifi DNA assembly and Transformation</button>

Adapted by Jacob Mejlsted & Joen Haahr Jensen from IDT's <a href="https://international.neb.com/-/media/catalog/datacards-or-manuals/manuale2621.pdf" target="_blank">HiFi assembly protocol</a>.

<li> Steril MilliQ water </li>

<li> Competent E. coli </li>

<li> Prepared DNA fragments for assembly (See information on primer construction) </li>

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<li>Set up the following reaction on ice:<br>* If the inserts are less less than 200 bp, use a 5 fold excess of inserts instead of a 2 fold excess <br>

** If a greater number of fragments are assembled, increase the volumen of the reaction and use additional HiFi DNA assembly master mix <br></li>

     <td class="tg-1wig">4-6 Fragements</td>

     <td class="tg-0lax">0.03-0.3pmols<br>X uL</td>

     <td class="tg-0lax">0.2-0.5 pmols<br>X uL</td>

     <td class="tg-0lax">10 uL</td>

     <td class="tg-kftd">10 uL</td>

     <td class="tg-kftd">10 uL</td>

     <td class="tg-kftd">10 uL</td>

     <td class="tg-kftd">MilliQ water</td>

     <td class="tg-0lax">10-X uL</td>

     <td class="tg-0lax">10-x uL</td>

     <td class="tg-0lax">0 uL</td>

     <td class="tg-kftd">20 uL</td>

     <td class="tg-kftd">20 uL</td>

     <td class="tg-kftd">20 uL</td>

<li>Incubate the reaction samples in a thermocycler at 50oC for 15 minutes (when 2-3 fragments are assembled) or 60 minutes (when 4-6 fragments are assembled). Following incubation, store the reaction samples at -20oC for subsequent transformation<br>Note: Extended incubation up to 60 minutes can in some cases improve transformation efficiency</li>

<li> Add 2 uL of the chilled assembly product to the competent cells. Mix gently by pipetting up or down or by flicking the tube 4-5 times. Do NOT vortex </li>

<li> Heat shock at 42oC for 30 seconds. Do not mix </li>

<li> Add 950 uL of room temperature SOC media to the tubes </li>

<li> Incubate the tube for 37oC for 60 minutes. shake vigerously (250 rpm) or rotate </li>

<li> Warm selection plates to 37oC </li>

<li> Spread 100uL of the cells onto the selection plates. </li>

<li> Incubate overnight at 37oC. </li>

This protocol is for linearising backbones with the PacI+Nt.BbvCI USER casette. This will allow assembly of PCR product with USER tails to be assembled into this linearised plasmid

<li> Plasmid: 40 uL </li>

<li> PacI: 2 uL </li>

<li> Cutsmart buffer (NEB): 10 uL </li>