Protocols

From 2008.igem.org

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A. '''PCR (25ul) or Wobble PCR (50ul)'''
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<html>
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::I. '''PCR (25ul)'''
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<head>
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::::1.  Mastermix: 20.375 ul water, 0.5ul 10mM dNTP, 2.5 ul 10x Buffer 2, 0.375 ul Expand Polymerase 1.
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<style>
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::::::a.  Aliquot 23.75 ul into each tube.
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#globalWrapper {
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::::2.  Add 0.5ul Oligo 1 (10uM), 0.5ul Oligo 2 (10uM), 0.25 ul template DNA.
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margin: 0px;
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::::3.  Load into thermocycler.  ''Note: small holes are for 0.2 ul tube and big holes for 0.5 ul to maximize contact''
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padding: 0px;
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::::4.  Select the program (55/45 if under 1kb, 2K55/2K45 for 1kb to 2kb, 4K55/45 for 2kb to 4kb, 8K55/45 if over 4kb)
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background-color: #717144 !important;
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}
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#header {
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background-color: #717144;
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width: 100%;
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height: 180px;
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background: url(https://static.igem.org/mediawiki/2008/7/77/JHU_0708_BubblesLogo.gif) no-repeat 0px top;
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}
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#footer-box {
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border-top-color: #717144;
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border-right-color: #717144;
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border-bottom-color: #717144;
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border-left-color: #717144;
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background: #717144;
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}
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#content{
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background:#717144;
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border-left-color: #717144;
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border-right-color: #717144;
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}
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#leftcol {
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background: #717144;
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float: left;
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width: 160px;
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height: 476px;
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}
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/*#name {
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                        border: 2px solid black;
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                        margin: 20 20 500 0;
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                        height: 30px;
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                        width: 90px;
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                }*/
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div#header a, div#leftcol a {
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position: relative;
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height: 118px;
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width: 118px;
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float: right;
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text-decoration: none;
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}
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        #divholder{
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                        margin-right: 0px;
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                }
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div#header a {
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bottom: 0px;
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margin: 65px 0 0 0;
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}
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                /*div#header a#Biobrick{margin-right:20px;}*/
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::II. '''Wobble PCR (50ul)'''
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/* leftcol nav */
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::::1. Mastermix: 40 ul water, 1.5 ul MgCl2, 5 ul buffer (Taq), 1 ul 10mM dNTP, 0.5 ul Taq Polymerase
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#Home { background-image: url(https://static.igem.org/mediawiki/2008/b/bd/JHU_0708_HomeB.gif); }
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::::::a. Aliquot 48 ul into each tube
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#Home:hover { background-image: url(https://static.igem.org/mediawiki/2008/0/06/JHU_0708_HomeH.gif); }
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::::2. Add 1 ul 100 uM Oligo 1, 1 ul 100 uM Oligo 2.
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#People { background-image: url(https://static.igem.org/mediawiki/2008/1/1b/JHU_0708_PeopleB.gif); }
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::::3. Load into thermocycler.
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#People:hover { background-image: url(https://static.igem.org/mediawiki/2008/8/87/JHU_0708_PeopleH.gif); }
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::::4. Select the program WOBBLE55 or WOBBLE45 and run.
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#Money { background-image: url(https://static.igem.org/mediawiki/2008/6/6b/JHU_0708_MoneyB.gif); }
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#Money:hover { background-image: url(https://static.igem.org/mediawiki/2008/1/16/JHU_0708_MoneyH.gif); }
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B.  '''Isolation and Visualization of PCR Product'''
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/* header nav */
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::1. Label new tubes with the names of your samples for isolation.
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#Research { background-image: url(https://static.igem.org/mediawiki/2008/0/04/JHU_0708_ResearchB.gif); }
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::2.  Open a 0.8% CloneWell E-Gel. ''Only do this unless you are planning on running it in less than 15 min or it will dry out!''
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#Research:hover { background-image: url(https://static.igem.org/mediawiki/2008/2/20/JHU_0708_ResearchH.gif); }
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::3.  Place E-gel in apparatus (don't remove combs yet!) and do a PreRun for 2 minutes.
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#Notebook { background: url(https://static.igem.org/mediawiki/2008/4/47/JHU_0708_NotebookB.gif); }
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::4. Remove combs and add about 25 ul of water to all cloning wells, 10 ul of ladder (GeneRuler, 1kb DNA Ladder) to the M lane, and 25 ul of your PCR products to each well. ''If you have fewer than 8 samples, try not to use the two outer lanes (1 and 8) since they tend to dry out/distort the DNA, and the water in these clone wells evaporated extremely quickly. Also, fill any unused lanes with 25 ul of water.''
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#Notebook:hover { background: url(https://static.igem.org/mediawiki/2008/1/11/JHU_0708_NotebookH.gif) }
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::5. Select Run CloneWell and hit Go. After about 1 minute, turn on the blue light and view the gel through the orange shield; you should see small, bright bands under your sample lanes. Every couple minutes, check to make sure the clone wells are still filled with water.
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#Biobrick { background: url(https://static.igem.org/mediawiki/2008/0/05/JHU_0708_BiobrickB.gif);}
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::6. Allow the bands to run until they reach the tiny horizontal scratches just above the clone wells. At this point, hit Go to stop the gel from running. Completely fill all clone wells with water and prepare for extraction.
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#Biobrick:hover { background: url(https://static.igem.org/mediawiki/2008/8/8c/JHU_0708_BiobrickH.gif); }
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::7. Hit Go to start again and watch until the band has mostly entered the clone well and water. Hit Go again to stop the gel.
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#Protocols { background: url(https://static.igem.org/mediawiki/2008/e/ee/JHU_0708_ProtocolsB.gif); }
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::8. Extract the water/sample from the clone well with a pipette and transfer to appropriately-labeled new tube. ''If you miss your sample and it has continued on past your clone well, you can stop the program and select a reverse run to get it back, but avoid doing this if you can''
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#Protocols:hover { background: url(https://static.igem.org/mediawiki/2008/a/a3/JHU_0708_ProtocolH.gif); }
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::9. Go ahead and freeze your samples if you don't plan on doing a digestion immediately.
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C.  '''Digestion (w/o DpnI)'''
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#book {
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::1. Combine 5 ul NEB2, x ul of your DNA samples from the CloneWell, 1 ul EcoRI, 1 ul BamHI, (43-x) ul water. ''It's usually safe to assume you'll have at least 15 ul of any given sample extracted from the E-gel, so if you have many samples make a master mix in which there are 15 ul of DNA sample and 28 ul of water and multiply accordingly depending on the number of samples you have.''
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float: top;
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::2. Incubate at 37 C for one hour.
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background: #FFFF99;
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width: 700px;
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/*height: 85%;*/
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border: 10px solid #FFFF99;
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margin-left: 160px;
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padding-right: 40px;
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padding-left: 10px;
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min-height: 450px;
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}
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}
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font.ir {
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font-size:85%;
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line-height:1.3;
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}
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a{color:#BFBFBF;text-decoration:none;}
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a:hover{color:#5888AB}
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a img{border:0px}
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a:visited {
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color: #000000;
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}
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</style>
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</head>
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D.  '''Clean-up with Zymo Columns'''
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<body>
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::I.  '''Products Greater Than 300 bp'''
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<div id="header">
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::::1.  Label each Zymo column and fresh Eppendorf tubes with the appropriate names of your samples.
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          <div id="divholder">
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::::2.  Add 200ul ADB buffer to each of the digestion samples, mix and pipette into zymo columns. Spin for 30 sec at full speed to pass the liquid through the column.
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                <div id="name"><font class=ir></font></div>
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::::3.  Empty collection tubes and put back onto the columns. Wash with 200 ul wash buffer and again spin for 30 sec at full speed. ''This will dissolve any extra guanidinium chloride and salts sitting on the membrane''
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<a href="Biobrick" id="Biobrick"></a>
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::::4.  Repeat the wash buffer step 3. ''Now nothing is present on the membrane but the DNA and a little ethanol and water''
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<a href="Protocols" id="Protocols"></a>
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::::5.  Now spin the column for 90 sec at full speed to remove all traces of water/ethanol.
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                <a href="Research" id="Research"></a>
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::::6.  Empty and discard the collection tube. Replace each collection tube with the appropriately-labeled fresh Eppendorf tubes.
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                <a href="Notebook" id="Notebook"></a>
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::::7.  Add 6 ul of water directly to each of the membranes of the Zymo columns, and spin for 45 sec to elute the DNA into your fresh Eppendorf tubes.
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          </div>
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::II.  '''Products Between 20 and 300 bp'''
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</div>
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::::1.  Add 1 volume equivalent of Zymo ADB buffer to each reaction. Vortex to mix.
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::::2.  Add 5 volumes of 95% ethanol (under fume hood, labeled flammable). Vortex to mix. ''The remaining steps are just like a normal Zymo clean-up reaction''
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::::1.  Label each Zymo column and fresh Eppendorf tubes with the appropriate names of your samples.
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::::2.  Transfer your reaction mixtures into Zymo columns. Spin for 30 sec at full speed to pass the liquid through the column.
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::::3.  Empty collection tubes and put back onto the columns. Wash with 200 ul wash buffer and again spin for 30 sec at full speed. ''This will dissolve any extra guanidinium chloride and salts sitting on the membrane''
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::::4.  Repeat the wash buffer step 3. ''Now nothing is present on the membrane but the DNA and a little ethanol and water''
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::::5.  Now spin the column for 90 sec at full speed to remove all traces of water/ethanol.
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::::6.  Empty and discard the collection tube. Replace each collection tube with the appropriately-labeled fresh Eppendorf tubes.
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::::7.  Add 6 ul of water directly to each of the membranes of the Zymo columns, and spin for 45 sec to elute the DNA into your fresh Eppendorf tubes.
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E.  Ligation
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<div id="leftcol">
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::1. Mastermix: 6.5ul water, 1ul ligation buffer, 0.5 T4 DNA ligase, 1ul pBca1256.  Aliquot 9ul.
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<a href="https://2008.igem.org/Team:Johns_Hopkins" id="Home"></a>
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::2.  Add 1ul of insert.
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<a href="People" id="People"></a>
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::3.  Cover with foil and incubate for 30 min at room temperature.
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<a href="Donations" id="Money"></a>
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</div>
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F.  Transformation (always keep on ice)
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<div id="book"><h2>Welcome to Johns Hopkins iGEM</h2>
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::1.  220ul competent cell in one tube. Thaw on ice.
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<p>
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::2.  Add 30ul KCM and 20 ul water (both cold) to each tube of competent cells.
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<font class=ir>
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::3.  Invert 2x to mix.
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&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;The International Genetically Engineered Machines Competition (iGEM) is an annual intercollegiate challenge that seeks to answer the question: "Can simple biological systems be built from standard, interchangeable parts and operated in living cells? Or is biology simply too complicated to be engineered in this way?" The newly-formed iGEM team at Johns Hopkins is composed of mostly undergraduate students with diverse majors ranging from Materials Science Engineering to Biology. While the team has graduate and faculty input, it is almost totally undergraduate run. The iGEM teams work over the summer at their, respective university, and then attend the iGEM Jamboree in November to present their work. We plan to create novel genetic parts that could be added to the existing iGEM registry of biological parts. The MIT iGEM Registry of Parts is the databank of biological standards to which iGEM teams from 2003 and onward have contributed. Currently, the databank only has 16 yeast "biobricks". These biobricks are reporters, tags, plasmids and other useful interchangeable genetic parts, that could one day revolutionize genetic and synthetic biology. By the end of our project, we will have most likely doubled the amount of yeast biobricks in the registry.
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::4.  Aliquot 45ul cell into 10 ul of ligation rxn. Swirl and pipette up and down once to mix.
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</font>
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::5. Foil all tubes and incubate 10 min in ice-water.
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</p>
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::6. Heat shock 90 sec at 42 C.
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<br></br>
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::7.  Incubate on ice for 2 min.
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</div>
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::8.  Rub ethanol and flame top of foil to sterilize. Add 50 ul of LB to each tube by poking holes into each tube with pipette tips.
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</body>
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::9.  Re-cover all tubes with foil.
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</html>
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::9.  Incubate for 1 hr at 37 C.
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::10. Plate
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Latest revision as of 04:05, 11 July 2008

Welcome to Johns Hopkins iGEM

        The International Genetically Engineered Machines Competition (iGEM) is an annual intercollegiate challenge that seeks to answer the question: "Can simple biological systems be built from standard, interchangeable parts and operated in living cells? Or is biology simply too complicated to be engineered in this way?" The newly-formed iGEM team at Johns Hopkins is composed of mostly undergraduate students with diverse majors ranging from Materials Science Engineering to Biology. While the team has graduate and faculty input, it is almost totally undergraduate run. The iGEM teams work over the summer at their, respective university, and then attend the iGEM Jamboree in November to present their work. We plan to create novel genetic parts that could be added to the existing iGEM registry of biological parts. The MIT iGEM Registry of Parts is the databank of biological standards to which iGEM teams from 2003 and onward have contributed. Currently, the databank only has 16 yeast "biobricks". These biobricks are reporters, tags, plasmids and other useful interchangeable genetic parts, that could one day revolutionize genetic and synthetic biology. By the end of our project, we will have most likely doubled the amount of yeast biobricks in the registry.